Objective optical system and observation apparatus provided with the same

ABSTRACT

An objective optical system of an embodiment according to the present invention is formed in such a way that: the objective optical system includes an immovable lens group which is arranged nearest to the object side, which is immovable in focusing, and which has negative power, and first and second movable lens groups at least one of which moves along the optical axis in focusing; and an amount of variation in magnification per movement of the first movable lens group is different from an amount of variation in magnification per movement of the second movable lens group.

This application claims benefits of Japanese Applications No. 2011-247521 filed in Japan on Nov. 11, 2011, No. 2011-247522 filed in Japan on Nov. 11, 2011, and No. 2012-022133 filed in Japan on Feb. 3, 2012, the contents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to an objective optical system which is provided with two movable lens groups moving along the optical axis, and relates to an observation apparatus having the same.

2. Description of Related Art

Objective optical systems having known up to now include an objective optical system in which a lens group is moved to change a state of the objective optical system suitable for normal observation (which is called “normal observation state” below) into a state of the objective optical system suitable for close-up observation (which is called “close-up observation state” below) so that the objective optical system is closed to a particular object optionally selected from a plurality of objects present in an observation area by an observer to make it possible to observe the particular object in detail.

Such objective optical systems include, for example, an objective optical system: which consists of a first lens group with negative power, a second lens group with positive power, a third lens group with negative power, a fourth lens group with positive power, and a fifth lens group with positive power, in that order from the object side; and in which focusing is performed by moving the second and third lens groups along the optical axis in the range from the normal observation state to the middle state and by moving the fifth lens group along the optical axis in the range from the middle state to the close-up observation state (refer to Japanese Patent Kokai No. 2007-155887).

In addition, there is also an objective optical system: which consists of a first lens group with positive power, a second lens group with negative power, and a third lens group with positive power, in that order from the object side; and in which a magnification is changed and focusing is performed by moving the second lens group (refer to Japanese Patent Kokai No. 2007-233036).

SUMMARY OF THE INVENTION

An objective optical system according to the present invention is characterized in that: the objective optical system includes an immovable lens group which is arranged nearest to the object side, which is immovable in focusing, and which has negative power, and first and second movable lens groups at least one of which moves along the optical axis in focusing; and an amount of variation in magnification per movement of the first movable lens group is different from an amount of variation in magnification per movement of the second movable lens group.

Also, an objective optical system according to the present invention, which can reversibly and continuously change its normal observation state into its close-up observation state by moving a predetermined lens group to change a magnification, is characterized in that: the objective optical system includes an immovable lens group which is arranged nearest to the object side, which is immovable in focusing and in the change from the normal observation state, and which has negative power, and first and second movable lens groups at least one of which moves along the optical axis in focusing; the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged; an amount of variation in magnification per movement of the first movable lens group is smaller than an amount of variation in magnification per movement of the second movable lens group; and the change from the normal observation state is made by moving the second movable lens group.

Also, an observation apparatus according to the present invention is characterized in that the observation apparatus includes an above-described objective optical system and an autofocus mechanism for moving the first movable lens group.

Also, an objective optical system according to the present invention, which can reversibly and continuously change its normal observation state into its close-up observation state by moving a predetermined lens group to change a magnification, is characterized in that: the objective optical system includes an immovable lens group which is arranged nearest to the object side and which is immovable in changing magnification and in focusing, a magnification-changing group which moves along the optical axis at least in changing magnification, and a focusing group which moves along the optical axis at least in focusing; the immovable lens group includes a lens having negative power, the lens with negative power being located nearest to the object side; the magnification-changing group is arranged nearer to the object side than the focusing group is arranged; an amount of variation in magnification per movement of the magnification-changing group is larger than an amount of variation in magnification per movement of the focusing group; and a change in magnification is made by moving the magnification-changing group.

Also, an observation apparatus according to the present invention is characterized in that the observation apparatus includes the above-described objective optical system and an autofocus mechanism for moving the focusing group.

These and other features and advantages of the present invention will become apparent from the following detailed description of the preferred embodiments when taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF DRAWINGS

FIGS. 1A to 1C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 1, where FIG. 1A shows the normal observation state of the optical system (in the farthest point state), FIG. 1B shows the middle state of the optical system (in the farthest point state), and FIG. 1C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 2A to 2C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 2, where FIG. 2A shows the normal observation state of the optical system (in the farthest point state), FIG. 2B shows the middle state of the optical system (in the farthest point state), and FIG. 2C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 3A to 3C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 3, where FIG. 3A shows the normal observation state of the optical system (in the farthest point state), FIG. 3B shows the middle state of the optical system (in the farthest point state), and FIG. 3C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 4A to 4L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 3A-3C. To be specific, FIGS. 4A to 4D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 4E to 4H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 4I to 4L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 5A to 5C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 4, where FIG. 5A shows the normal observation state of the optical system (in the farthest point state), FIG. 5B shows the middle state of the optical system (in the farthest point state), and FIG. 5C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 6A to 6L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 5A-5C. To be specific, FIGS. 6A to 6D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 6E to 6H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 6I to 6L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 7A to 7C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 5, where FIG. 7A shows the normal observation state of the optical system (in the farthest point state), FIG. 7B shows the middle state of the optical system (in the farthest point state), and FIG. 7C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 8A to 8L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 7A-7C. To be specific, FIGS. 8A to 8D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 8E to 8H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 8I to 8L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 9A to 9C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 6, where FIG. 9A shows the normal observation state of the optical system (in the farthest point state), FIG. 9B shows the middle state of the optical system (in the farthest point state), and FIG. 9C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 10A to 10L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 9A-9C. To be specific, FIGS. 10A to 10D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 10E to 10H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 10I to 10L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 11A to 11C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 7, where FIG. 11A shows the normal observation state of the optical system (in the farthest point state), FIG. 11B shows the middle state of the optical system (in the farthest point state), and FIG. 11C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 12A to 12L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 11A-11C. To be specific, FIGS. 12A to 12D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 12E to 12H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 12I to 12L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 13A to 13C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 8, where FIG. 13A is shows the normal observation state of the optical system (in the farthest point state), FIG. 13B shows the middle state of the optical system (in the farthest point state), and FIG. 13C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 14A to 14L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 13A-13C. To be specific, FIGS. 14A to 14D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 14E to 14H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 14I to 14L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 15A to 15C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 9, where FIG. 15A shows the normal observation state of the optical system (in the farthest point state), FIG. 15B shows the middle observation state of the optical system (in the farthest point state), and FIG. 15C show the close-up observation state of the optical system (in the farthest point state).

FIGS. 16A to 16L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 15A-15C. To be specific, FIGS. 16A to 16D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 16E to 16H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 16I to 16L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 17A to 17C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 10, where FIG. 17A shows the normal observation state of the optical system (in the farthest point state), FIG. 17B shows the middle observation state of the optical system (in the farthest point state), and FIG. 17C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 18A to 18L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 17A-17C. To be specific, FIGS. 18A to 18D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 18E to 18H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 18I to 18L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 19A to 19C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 11, where FIG. 19A shows the normal observation state of the optical system (in the farthest point state), FIG. 19B shows the middle observation state of the optical system (in the farthest point state), and FIG. 19C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 20A to 20L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 19A-19C, where FIGS. 20A to 20D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 20E to 20H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 20I to 20L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 21A to 21C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 12, where FIG. 21A shows the normal observation state of the optical system (in the farthest point state), FIG. 21B shows the middle observation state of the optical system (in the farthest point state), and FIG. 21C shows a view showing the close-up observation state of the optical system (in the farthest point state).

FIGS. 22A to 22L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 21A-21C. To be specific, FIGS. 22A to 22D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 22E to 22H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 22I to 22L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 23A to 23C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 13, where FIG. 23A shows the normal observation state of the optical system (in the farthest point state), FIG. 23B shows the middle observation state of the optical system (in the farthest point state), and FIG. 23C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 24A to 24L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 23A-23C. To be specific, FIGS. 24A to 24D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 24E to 24H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 24I to 24L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 25A to 25C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 14, where FIG. 25A shows the normal observation state of the optical system (in the farthest point state), FIG. 25B shows the middle observation state of the optical system (in the farthest point state), and FIG. 25C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 26A to 26L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 25A-25C. To be specific, FIGS. 26A to 26D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 26E to 26H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 26I to 26L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 27A to 27C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 15, where FIG. 27A shows the normal observation state of the optical system (in the farthest point state), FIG. 27B shows the middle observation state of the optical system (in the farthest point state), and FIG. 27C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 28A to 28L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 27A-27C. To be specific, FIGS. 28A to 28D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 28E to 28H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 28I to 28L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 29A to 29C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 16, where FIG. 29A shows the normal observation state of the optical system (in the farthest point state), FIG. 29B shows the middle observation state of the optical system (in the farthest point state), and FIG. 29C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 30A to 30L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 29A-29C. To be specific, FIGS. 30A to 30D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 30E to 30H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 30I to 30L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 31A to 31C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 17, where FIG. 31A shows the normal observation state of the optical system (in the farthest point state), FIG. 31B shows the middle observation state of the optical system (in the farthest point state), and FIG. 31C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 32A to 32L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 31A-31C. To be specific, FIGS. 32A to 32D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 32 to 32H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 32I to 32L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 33A to 33C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 18, where FIG. 33A shows the normal observation state of the optical system (in the farthest point state), FIG. 33B shows the middle observation state of the optical system (in the farthest point state), and FIG. 33C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 34A to 34L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 33A-33C. To be specific, FIGS. 34A to 34D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 34E to 34H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 34I to 34L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 35A to 35C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 19, where FIG. 35A shows the normal observation state of the optical system (in the farthest point state), FIG. 35B shows the middle observation state of the optical system (in the farthest point state), and FIG. 35C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 36A to 36L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 35A-35C. To be specific, FIGS. 36A to 36D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 36E to 36H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 36I to 36L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 37A to 37C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 20, where FIG. 37A is a view showing the normal observation state of the optical system (in the farthest point state), FIG. 37B shows the middle observation state of the optical system (in the farthest point state), and FIG. 37C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 38A to 38L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 37A-37C. To be specific, FIGS. 38A to 38D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 38E to 38H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 38I to 38L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 39A to 39C are sectional view taken along the optical axis for showings the configuration of the optical system provided for the observation apparatus according to Embodied Example 21, where FIG. 39A shows the normal observation state of the optical system (in the farthest point state), FIG. 39B shows the middle observation state of the optical system (in the farthest point state), and FIG. 39C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 40A to 401L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 39A-39C. To be specific, FIGS. 40A to 40D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 40E to 40H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 40I to 40L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIGS. 41A to 41C are sectional views taken along the optical axis for showing the configuration of the optical system provided for the observation apparatus according to Embodied Example 22, where FIG. 41A shows the normal observation state of the optical system (in the farthest point state), FIG. 41B shows the middle observation state of the optical system (in the farthest point state), and FIG. 41C shows the close-up observation state of the optical system (in the farthest point state).

FIGS. 42A to 42L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 41A-41C. To be specific, FIGS. 42A to 42D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 42E to 42H show the aberrations in the middle observation state of the optical system (in the farthest point state), and FIGS. 42I to 42L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

FIG. 43 is a view showing the whole of an endoscope provided with an objective optical system according to the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Prior to explanations about the Embodied Examples, operation effects in embodiments of the present invention will be explained. Besides, when the operation effects in the embodiments are specifically explained, the operation effects are to be explained while specific examples are being shown. However, the illustrated embodiments are insistently merely a part of embodiments included by the present invention as well as below-described Embodied Examples, and the embodiments included by the present invention include numerous variations. Accordingly, the present invention is not limited to the below-illustrated embodiments.

Besides, a state in which a magnification produced by a movable lens group mainly playing a role as a component changing magnification or a magnification-changing group has the minimum value is called “normal observation” state, a state in which a magnification produced by a movable lens group mainly playing a role as a component changing magnification or a magnification-changing group has the maximum value is is called “close-up observation” state, and a state in which a magnification produced by a movable lens group mainly playing a role as a component changing magnification or a magnification-changing group has a value between the normal observation state and the close-up observation state is called “middle observation” state, below. Also, a state in which a magnification produced by a movable lens group mainly playing a role as a component performing focusing or a focusing group has the minimum value is called “the farthest point” state, and a state in which a magnification produced by a movable lens group mainly playing a role as a component performing focusing or a focusing group has the maximum value is called “the nearest point” state, below.

An objective optical system of an embodiment according to the present invention is characterized in that: the objective optical system includes an immovable lens group which is arranged nearest to the object side, which is immovable in focusing, and which has negative power, and first and second movable lens groups at least one of which moves along the optical axis in focusing; and an amount of variation in magnification per movement of the first movable lens group is different from an amount of variation in magnification per movement of the second movable lens group.

As described above, in the objective optical system of the present embodiment, the immovable lens group immovable in focusing and having negative power is arranged nearest to the object side.

As a result, the objective optical system of the present embodiment has a structure which makes an angle of view wide and makes it easy to observe an object to be imaged while the objective optical system is close to the object to be imaged, or makes it easy to perform close-up observation.

Also, as described above, the objective optical system of the present embodiment is provided with two movable lens groups which differ from each other in amount of variation in magnification per movement of each of the lens groups.

Accordingly, in the objective optical system of the present embodiment, the movable lens group having a large amount of variation in magnification per its movement is mainly moved when a distance from the objective optical system to an object to be imaged varies widely, and the movable lens group having a small amount of variation in magnification per its movement is mainly moved when a distance from the objective optical system to the object to be imaged varies minutely. As a result, it is possible to reduce changes in observation magnification and in angle of view in focusing. As a result, the objective optical system of the present embodiment makes it possible to perform highly accurate focusing while variations in field curvature and in chromatic aberration of magnification are being checked.

Also, the objective optical system of the present embodiment may be formed in such a way that: the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged; and an amount of variation in magnification per movement of the first movable lens group is larger than an amount of variation in magnification per movement of the second movable lens group.

In the case where the objective optical system of the present embodiment is formed in such a manner, it is hard for the normal observation state and the close-up observation state to widely differ from each other in difference amount occurring on an image-formation plane in performing focusing by the second movable lens group having a small amount of variation in magnification.

Also, the objective optical system of the present embodiment may be formed in such a way that: the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged; and an amount of variation in magnification per movement of the first movable lens group is smaller than an amount of variation in magnification per movement of the second movable lens group.

In the case where the objective optical system of the present embodiment is formed in such a manner, or in the case where the first movable lens group having a small amount of variation in magnification is arranged at a position at which movement of the first movable lens group has a small influence on angle of view, it is hard for angle of view to vary in focusing. Also, a difference amount on the image-formation plane in performing focusing by the first movable lens group becomes large, so that it is possible to reduce a distance range in which the first movable lens group can move, and it is possible to downsize its focusing mechanism.

Also, an objective optical system of an embodiment according to the present invention, which can reversibly and continuously change its normal observation state into its close-up observation state by moving a predetermined lens group, is characterized in that: the objective optical system includes an immovable lens group which is arranged nearest to the object side, which is immovable in focusing and in the change from the normal observation state, and which has negative power, and first and second movable lens groups at least one of which moves along the optical axis in focusing; the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged; an amount of variation in magnification per movement of the first movable lens group is smaller than an amount of variation in magnification per movement of the second movable lens group; and the change from the normal observation state is made by moving the second movable lens group.

As described above, in the optical objective system of the present embodiment, the immovable lens group immovable in focusing and having negative power is arranged nearest to the object side.

As a result, the objective optical system of the present embodiment brings a wide angle of view and makes it easy to observe an object to be imaged while the objective optical system is being focused on the object to be imaged, or makes it easy to perform close-up observation.

Also, as described above, in the objective optical system of the present embodiment, a change from the normal observation state to the close-up observation state is continuously made by moving the second movable lens group with a large amount of variation in magnification per its movement. And, focusing is performed not only by the second movable lens group but also by the first movable lens group with a small amount of variation in magnification per its movement in the change from the normal observation state to the close-up observation state.

As a result, even though a focal depth becomes shallow because the objective optical system is in the close-up observation state as a result of movement of the second movable lens group, it is possible to perform focusing by the first movable lens group which causes small variations in observation magnification and in angle of view, and the objective optical system of the present embodiment makes it easy to perform highly accurate focusing while variations in field curvature and in chromatic aberration of magnification are being checked.

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (1): 3<(m _(c-d) /m _(u-d))/(m _(c-n) /m _(c-d))<10  (1) where, m_(c-d) denotes transverse magnification of the whole of the system in the farthest point state and in the close-up observation state, m_(u-d) a denotes transverse magnification of the whole of the system in the farthest point state and in the normal observation state, m_(c-n) denotes transverse magnification of the whole of the system in the nearest point state and in the close-up observation state, m_(c-n)/m_(c-d) denotes an amount of variation in magnification of the first movable lens group, and m_(c-d)/m_(u-d) denotes an amount of variation in magnification of the second movable lens group.

If (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) is below the lower limit of the condition (1), an amount of variation in magnification caused by the first movable lens group is large, so that its focusing function easily deteriorates. On the other hand, if (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) is beyond the upper limit of the condition (1), an amount of variation in magnification caused by the second movable lens group is large, so that the usability of the system in observing an object to be imaged easily deteriorates.

Besides, it is more preferred that the objective optical system of the present embodiment satisfies one of the following conditions (1-1) and (1-2) instead of the condition (1): 3.8<(m _(c-d) /m _(u-d))/(m _(c-n) /m _(c-d))<10  (1-1) 4.4<(m _(c-d) /m _(u-d))/(m _(c-n) /m _(c-d))<7.7  (1-2)

Also, the upper limit of the condition (1-1) may be used as the upper limit of the condition (1) or (1-2), or the lower limit of the condition (1-1) may be used as the lower limit of the condition (1) or (1-2). Also, the upper limit of the condition (1-2) may be used as the upper limit of the condition (1) or (1-1), or the lower limit of the condition (1-2) may be used as the lower limit of the condition (1) or (1-1).

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (2): 1<m _(c-n) /m _(c-d)<1.55  (2) where, m_(c-n) denotes transverse magnification of the whole of the system in the nearest point state and in the close-up observation state, m_(c-d) denotes transverse magnification of the whole of the system in the farthest point state and in the close-up observation state, and m_(c-n)/m_(c-d) denotes an amount of variation in magnification of the first movable lens group.

If m_(c-n)/m_(c-d) is beyond the upper limit of the condition (2), variations in magnification in focusing are large, so that the usability of the system in observing an object to be imaged easily deteriorates.

Besides, it is more preferred that the objective optical system satisfies one of the following conditions (2-1) and (2-2) instead of the condition (2): 1<m _(c-n) /m _(c-d)<1.45  (2-1) 1<m _(c-n) /m _(c-d)<1.35  (2-2)

Also, it is preferred that: the objective optical system of the present embodiment includes a lens group which is located nearer than the image side than the first movable lens group is located; and the objective optical system satisfies the following condition (3): 0.2<|(1−β₁·β₁)×β₁′·β₁∝|<3  (3) where, β₁ denotes transverse magnification of the first movable lens group and β₁′ denotes transverse magnification of the lens group which is located nearer to the image side than the first movable lens group is.

If |(1−β₁·β₁)×β₁′·β₁′| is below the lower limit of the condition (3), an amount of the first movable lens group moving in focusing is large, so that the whole of the optical system easily has a large size. On the other hand, if |(1−β₁·β₁)×β₁′·β₁′| is beyond the upper limit of the condition (3), field curvature easily varies large.

Besides, it is more preferred that the objective optical system satisfies one of the following conditions (3-1) and (3-2) instead of the condition (3): 0.3<|(1−β₁·β₁)×β₁′·β₁′|<3  (3-1) 0.5<|(1−β₁·β₁)×β₁′·β₁′|<2.5  (3-2)

Also, the upper limit of the condition (3-1) may be used as the upper limit of the condition (3) or (3-2), or the lower limit of the condition (3-1) may be used as the lower limit of the condition (3) or (3-2). Also, the upper limit of the condition (3-2) may be used as the upper limit of the condition (3) or (3-1), or the lower limit of the condition (3-2) may be used as the lower limit of the condition (3) or (3-1).

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (4): 2<|F ₁ /F _(c-d)|<8  (4) where, F₁ denotes focal length of the first movable lens group and F_(c-d) denotes focal length of the whole of the optical system in the farthest point state and in the close-up observation state.

If |F₁/F_(c-d)| is below the lower limit of the condition (4), power of the first movable lens group is strong, so that field curvature easily varies large in focusing and resolution is easily deteriorates. On the other hand, if |F₁/F_(c-d)| is beyond the upper limit of the condition (4), power of the first movable lens group is weak, so that a moving distance necessary in focusing easily becomes large and the whole of the optical system easily has a large size.

Besides, it is more preferred that the objective optical system of the present embodiment satisfies one of the following conditions (4-1) and (4-2) instead of the condition (4): 3<|F ₁ /F _(c-d)|<7  (4-1) 3.2<|F ₁ /F _(c-d)|<6  (4-2)

Also, the upper limit of the condition (4-1) may be used as the upper limit of the condition (4) or (4-2), or the lower limit of the condition (4-1) may be used as the lower limit of the condition (4) or (4-2). Also, the upper limit of the condition (4-2) may be used as the upper limit of the condition (4) or (4-1), or the lower limit of the condition (4-2) may be used as the lower limit of the condition (4) or (4-1).

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (5): 1.8<|F ₂ /F _(c-d)|<5  (5) where, F₂ denotes focal length of the second movable lens group and F_(c-d) denotes focal length of the whole of the optical system in the farthest point state and in the close-up observation state.

If |F₂/F_(c-d)| is below the lower limit of the condition (5), power of the second movable lens group is weak, a moving distance necessary in changing magnification or in focusing easily becomes large and the whole of the optical system easily has a large size. On the other hand, if |F₂/F_(c-d)| is beyond the upper limit of the condition (5), power of the second movable lens group is strong, so that chromatic aberration of magnification or field curvature easily deteriorates.

Besides, it is more preferred that the objective optical system of the present embodiment satisfies one of the following conditions (5-1) and (5-2) instead of the condition (5): 1.8<|F ₂ /F _(c-d)|<4.5  (5-1) 2<|F ₂ /F _(c-d)|<4  (5-2)

Also, the upper limit of the condition (5-1) may be used as the upper limit of the condition (5) or (5-2), or the lower limit of the condition (5-1) may be used as the lower limit of the condition (5) or (5-2). Also, the upper limit of the condition (5-2) may be used as the upper limit of the condition (5) or (5-1), or the lower limit of the condition (5-2) may be used as the lower limit of the condition (5) or (5-1).

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (6): 0.02<D ₁ /L<0.12  (6) where, D₁ denotes the sum of an air distance from a lens group located on the object side of the first movable lens group to the first movable lens group and an air distance from the first movable lens group to a lens group located on the image side of the first movable lens group, and L denotes the total length of the whole of the optical system.

If D₁/L is below the lower limit of the condition (6), a necessary space in focusing by the first movable lens group is difficult to secure, so that the first movable lens group has to be made to have strong power, and various aberrations easily deteriorate. On the other hand, if D₁/L is beyond the upper limit of the condition (6), a distance which the first movable lens group covers in focusing is large, so that the whole of the optical system easily has a large size.

Besides, it is more preferred that the objective optical system of the present embodiment satisfies one of the following conditions (6-1) and (6-2) instead of the condition (6): 0.03<D ₁ /L<0.11  (6-1) 0.04<D ₁ /L<0.10  (6-2)

Also, the upper limit of the condition (6-1) may be used as the upper limit of the condition (6) or (6-2), or the lower limit of the condition (6-1) may be used as the lower limit of the condition (6) or (6-2). Also, the upper limit of the condition (6-2) may be used as the upper limit of the condition (6) or (6-1), or the lower limit of the condition (6-2) may be used as the lower limit of the condition (6) or (6-1).

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (7): |DT _(c-n) −DT _(c-d)|<5  (7) where, DT_(c-n) denotes distortion at image height ratio of 1.0 in the nearest point state and in the close-up observation state and DT_(c-d) denotes distortion at an image height ratio of 1.0 in the farthest point state and in the close-up observation state.

If |DT_(c-n)−DT_(c-d)| is beyond the upper limit of the condition (7), distortion in focusing by the first movable lens group easily varies large.

Besides, it is more preferred that the objective optical system satisfies one of the following conditions (7-1) and (7-2) instead of the condition (7): |DT _(c-n) −DT _(c-d)|<4  (7-1) |DT _(c-n) −DT _(c-d)|<2  (7-2)

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (8): DT _(u-d)<−50  (8) where, DT_(u-d) denotes distortion at an image height ratio of 1.0 in the farthest point state and in the normal observation state.

If DT_(u-d) is beyond the upper limit of the condition (8), it becomes difficult to observe a wide area and the usability of the system easily deteriorates. In addition, an amount of light incident on the edge portions of its lenses decreases, so that the edge potion of an acquired image easily became dark.

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (9): Fno _(u) /Fno _(c)>0.94  (9) where, Fno_(u) denotes the F number of the whole of the optical system in the normal observation state and Fno_(c) denotes the F number of the whole of the optical system in the close-up observation state.

Such a constitution of the optical system of the present embodiment makes it easy to secure a sufficient focal depth in each of variation-in-magnification states in a range from the normal observation state to the close-up observation state even though the objective optical system is used in combination with image-pickup elements each having a large number of pixels. It is because the F number in the normal observation state is approximately equal to the F number in the close-up observation state, so that there is no necessity that the F number in the normal observation state is reduced more than necessary even though the F number in the close-up observation state is reduced so as not to be affected by diffraction.

Besides, if Fno_(u)/Fno_(c) is below the lower limit of the condition (9), the F number in the normal observation state easily becomes small more than necessary when the F number in the close-up observation state is reduced up to diffraction limit.

Also, it is preferred that: the objective optical system of the present embodiment consists of five lens groups; the second lens group from the object side of the five lens groups is the first movable lens group; and the fourth lens group from the object side of the five lens groups is the second movable lens group.

Such a constitution of the optical system of the present embodiment makes it easy to perform highly accurate focusing while variations in field curvature and in chromatic aberration of magnification are small with respect to particular objects to be imaged. Particularly, the objective optical system having this constitution is very suitable to be used as an objective optical system for endoscopes or the like.

Also, an observation apparatus of an embodiment according to the present invention is characterized in that the observation apparatus is provided with one of the above-described objective optical systems and an autofocus mechanism for moving the first movable lens group.

Besides, for example, the autofocus mechanism is composed of: a drive mechanism which moves the first movable lens group along the optical axis; and a control means which controls the drive mechanism on the basis of predetermined information (information on images formed on an image pickup element in the case where the image pickup element like CCD is arranged on the image side of the objective optical system, information on a distance between the top of the objective optical system and an object to be observed, and so on).

Also, an objective optical system of an embodiment according to the present invention, which can reversibly and continuously change its normal observation state into its close-up observation state by moving a predetermined lens group to change magnification, is characterized in that: the objective optical system includes an immovable lens group which is arranged nearest to the object side and which is immovable in changing magnification and in focusing, a magnification-changing group which moves along the optical axis at least in changing magnification, and a focusing group which moves along the optical axis at least in focusing; the immovable lens group includes a lens having negative power, the lens with negative power being located nearest to the object side; the magnification-changing group is arranged nearer to the object side than the focusing group is arranged; an amount of variation in magnification per movement of the magnification-changing group is larger than an amount of variation in magnification per movement of the focusing group; and a change in magnification is made by moving the magnification-changing group.

As described above, in the optical objective system of the present embodiment, the immovable lens group immovable in focusing is arranged nearest to the object side. And, the immovable lens group includes the lens which is arranged nearest to the object side and which has negative power.

As a result, in the objective optical system of the present embodiment, an angle of view is wide and it is easy to observe an object to be imaged while the optical system is being focused on the object, that is to say, it is easy to perform close-up observation.

Also, as described above, in the objective optical system of the present embodiment, the normal observation state is changed into the close-up observation state to continuously change magnification by moving the magnification-changing group with a large amount of variation in magnification per its movement. And, focusing is performed not only by the magnification-changing group but also by the focusing group with a small amount of variation in magnification per its movement in the change from the normal observation state to the close-up observation state.

As a result, even though the objective optical system is made to reach the close-up observation state with a shallow focal depth by moving the magnification-changing group, it is possible to perform highly accurate focusing while variations in field curvature and in chromatic aberration of magnification are being checked with a small degree of variations in field curvature and in chromatic aberration of magnification, by performing focusing by the focusing group the movement of which brings small variations in observation magnification and in angle of view. In addition, variations in observation images in focusing can be checked in the objective optical system of the present embodiment, so that it is possible to suppress eyestrain suffered by observers.

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (10): 3<(m _(c-d) /m _(u-d))/(m _(c-n) /m _(c-d))<11  (10) where, m_(c-d) denotes transverse magnification of the whole of the system in the close-up observation state (in the farthest point state), m_(u-d) a denotes transverse magnification of the whole of the system in the normal observation state (in the farthest point state), and m_(c-n) denotes transverse magnification of the whole of the system in the close-up observation state (in the nearest point state).

Such a constitution of objective optical system satisfying the condition (10) makes it possible to reduce variations in field curvature and in chromatic aberration of magnification in changing magnification and in focusing, so that variations in the edge portions of observation images can be checked, the usability of the optical system in observing an object to be imaged becomes good, and it is easy to suppress eyestrain suffered by observers. If (m_(c-d)/m_(u-d))/(m_(c-d)/m_(c-d)) is below the lower limit of the condition (10), an amount of variation in magnification is large, so that it is difficult to make its focusing function good. On the other hand, if (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) is beyond the upper limit of the condition (10), it is difficult to reduce variation in field curvature in focusing.

Besides, it is more preferred that the objective optical system of the present embodiment satisfies one of the following conditions (10-1) and (10-2) instead of the condition (10): 3.1<(m _(c-d) /m _(u-d))/(m _(c-n) /m _(c-d))<10.5  (10-1) 3.2<(m _(c-d) /m _(u-d))/(m _(c-n) /m _(c-d))<9  (10-2)

Also, the lower limit of the condition (10-1) may be used as the lower limit of the condition (10-2). Also, the lower limit of the condition (10-2) may be used as the lower limit of the condition (10) or (10-1), or the upper limit of the condition (10-2) may be used as the upper limit of the condition (10) or (10-1).

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (11) when the focusing group moves in such a way an image plane moves by ± (F number×0.005) mm in a region from the farthest point to the nearest point in the close-up observation state: |ΔDT _(f)|<2  (11) where, ΔDT_(f) denotes variation in distortion when the focusing group moves.

If |ΔDT_(f)| is beyond the upper limit of the condition (11), a variation in distortion becomes large even though an image plane moves minutely (or by (F number×0.005) mm) That is to say, an observation image varies violently in observing an object to be imaged, so that fatigue suffered by observers easily become large.

Besides, it is more preferred that the objective optical system of the present embodiment satisfies one of the following conditions (11-1) and (11-2) instead of the condition (11): |ΔDT _(f)|<1.8  (11-1) |ΔDT _(f)|<1.5  (11-2)

Also, it is preferred that: the objective optical system of the present embodiment includes a lens group which is located nearer than the image side than the focusing group is located; and the objective optical system satisfies the following condition (12): 0.2<|(1−β_(f)·β_(f))×β_(f)′·β_(f)′|<0.9  (12) where, β_(f) denotes transverse magnification of the focusing group in the close-up observation state (in the farthest point state), and β_(f)′ denotes transverse magnification of the lens group which is located nearer to the image side than the focusing group is, in the close-up observation state (in the farthest point state).

Also, in the objective optical system of the present embodiment, it is preferred that: the focusing group is arranged nearest to the image side; and the objective optical system satisfies the following condition (12)′: 0.2<(1−β_(f)·β_(f))<0.9  (12)′ where, β_(f) denotes transverse magnification of the focusing group in the close-up observation state and in the farthest point state.

If |(1−β_(f)·β_(f))×β_(f)′·β_(f)′ | is below the lower limit of the condition (12) or (1−β_(f)·β_(f)) is below the lower limit of the condition (12)′, an amount of the focusing group moving in focusing is large, so that it is difficult to downsize the whole of the optical system. On the other hand, if |(1-β_(f)·β_(f))×β_(f)′·β_(f)′| is beyond the upper limit of the condition (12) or (1−β_(f)·β_(f)) is beyond the upper limit of the condition (12)′, it is difficult to reduce a variation in field curvature in focusing.

Besides, it is more preferred that the objective optical system of the present embodiment satisfies one of the following conditions (12-1) and (12-2) instead of the condition (12): 0.3<|(1−β_(f)·β_(f))×β_(f)′·β_(f)′|<0.8  (12-1) 0.3<|(1−β_(f)·β_(f))×β_(f)′·β_(f)′|<0.7  (12-2)

Also, the lower limit of the condition (12-1) may be used as the lower limit of the condition (12) or (12-2), or the upper limit of the condition (12-1) may be used as the upper limit of the condition (12) or (12-2). Also, the upper limit of the condition (12-2) may be used as the upper limit of the condition (12).

Also, it is more preferred that the objective optical system of the present embodiment satisfies one of the following conditions (12-1)′ and (12-2)′ instead of the condition (12)′: 0.3<(1−β_(f)·β_(f))<0.8  (12-1)′ 0.3<(1−β_(f)·β_(f))<0.7  (12-2)′

Also, the lower limit of the condition (12-1)′ may be used as the lower limit of the condition (12)′ or (12-2)′ or the upper limit of the condition (12-1)′ may be used as the upper limit of the condition (12)′ or (12-2)′. Also, the upper limit of the condition (12-2)′ may be used as the upper limit of the condition (12)′.

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (13): 1<|m _(c-n) /m _(c-d)|<2  (13) where, m_(c-n) denotes transverse magnification of the whole of the system in the close-up observation state (in the nearest point state), and m_(c-d) denotes transverse magnification of the whole of the system in the close-up observation state (in the farthest point state).

If |m_(c-n)/m_(c-d)| is below the lower limit of the condition (13), the objective optical system does not play a role as an optical system. On the other hand, if |m_(c-n)/m_(c-d)| is beyond the upper limit of the condition (13), variation in magnification in focusing is large, so that it is difficult to make its focus function good.

Besides, it is more preferred that the objective optical system satisfies one of the following conditions (13-1) and (13-2) instead of the condition (13): 1<|m _(c-n) /m _(c-d)|<1.85  (13-1) 1<|m _(c-n) /m _(c-d)|<1.65  (13-2)

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (14): 0.7<|F _(f) /F _(v)|<8  (14) where, F_(f) denotes focal length of the focusing group and F_(v) denotes focal length of the magnification-changing group.

If |F_(f)/F_(v)| is below the lower limit of the condition (14), variation in field curvature in focusing is large, so that it is difficult to make its image-forming function good. On the other hand, if |F_(f)/F_(v)| is beyond the upper limit of the condition (14), variation in distortion in focusing is large, so that it is difficult to make its focusing function good.

Besides, it is more preferred that the objective optical system of the present embodiment satisfies one of the following conditions (14-1) and (14-2) instead of the condition (14): 1.65<|F _(f) /F _(v)|<8  (14-1) 2<|F _(f) /F _(v)|<8  (14-2)

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (15): |γ|<11.5  (15) where, γ denotes an angle between: a principal ray of light emitting from the lens nearest to the image side in the focusing group and forming an image of an image height ratio of 1.0; and the optical axis in the close-up observation state (in the nearest point state).

If |γ| is beyond the upper limit of the condition (15), variation in field curvature in focusing is large, so that it is difficult to make its focusing function good.

Besides, it is more preferred that the objective optical system of the present embodiment satisfies one of the following conditions (15-1) and (15-2) instead of the condition (15): |γ|<10  (15-1) |γ|<9.2  (15-2)

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (16): |DT _(c-n) −DT _(c-d)|<5  (16) where, DT_(c-n) denotes distortion of an image with an image height ratio of 1.0 in the close-up observation state (in the nearest point state) and DT_(c-d) denotes distortion of an image with an image height ratio of 1.0 in the close-up observation state (in the farthest point state).

If |DT_(c-n)−DT_(c-d)| is beyond the upper limit of the condition (16), distortion in focusing varies large, so that the edge portion of an observation image easily distorts.

Besides, it is more preferred that the objective optical system of the present embodiment satisfies one of the following conditions (16-1) and (16-2) instead of the condition (16): |DT _(c-n) −DT _(c-d)|<4  (16-1) |DT _(c-n) −DT _(c-d)|<3  (16-2)

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (17): DT ₁₃₅<−50  (17) where, DT₁₃₅ denotes distortion at an angle of view of 135 degrees.

If DT₁₃₅ is beyond the upper limit of the condition (17), it is difficult to improve a resolution in the vicinity of the middle of an observation image, and it is difficult to observe a wide area. In addition, an amount of light on its edge portion decreases, so that the edge portion of the acquired image easily becomes dark.

Also, it is preferred that the magnification-changing group and/or the focusing group consists of a single lens component in the objective optical system of the present embodiment.

When the objective optical system of the present embodiment is formed in such a manner, the structure of the objective optical system can be easily simplified. In addition, it is easy to simplify control of its mechanisms. Besides, in this case, the above single lens components constituting magnification-changing groups or focusing groups include cemented lenses.

Also, it is preferred that: the objective optical system of the present embodiment is provided with a stop: and the focusing group is arranged nearer to the image side than the stop is arranged.

When the objective optical system of the present embodiment is formed in such a manner, it is easy to check a change in an observation image due to the movement of the focusing group. In addition, variation in distortion can be reduced, so that it is easy to check a change in angle of view.

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (18): 2<|F _(f) /F _(c-d)|<15  (18) where, F_(f) denotes focal length of the focusing group and F_(c-d) denotes focal length of the whole of the optical system in the close-up observation state (in the farthest point state).

If |F_(f)/F_(c-d)| is below the lower limit of the condition (18), power of the focusing group is strong and chromatic aberration of magnification or field curvature easily varies large in focusing, so that it is difficult to make its image-forming function good. On the other hand, if |F_(f)/F_(c-d)| is beyond the upper limit of the condition (18), power of the focusing group is weak, a moving distance necessary to move the focusing group in focusing easily becomes large, so that it is difficult to downsize the whole of the optical system.

Besides, it is more preferred that the objective optical system satisfies one of the following conditions (18-1) and (18-2) instead of the condition (18): 3<|F _(f) /F _(c-d)|<15  (18-1) 4<|F _(f) /F _(c-d)|<14  (18-2)

Also, the lower limit of the condition (18-1) may be used as the lower limit of the condition (18-2). Also, the lower limit of the condition (18-2) may be used as the lower limit of the condition (18) or (18-1), or the upper limit of the condition (18-2) may be used as the upper limit of the condition (18) or (18-1).

Also, it is preferred that the objective optical system of the present embodiment satisfies the following condition (19): 0.83<Fno _(u) /Fno _(c)  (19) where, Fno_(u) denotes the F number of the whole of the optical system in the normal observation state (in the farthest point state) and Fno_(c) denotes the F number of the whole of the optical system in the close-up observation state (in the farthest point state).

Such a constitution of the optical system of the present embodiment makes it easy to secure a sufficient focal depth in each of variation-in-magnification states in a range from the normal observation state to the close-up observation state even though the objective optical system is used in combination with image-pickup elements each having a large number of pixels. It is because the F number in the normal observation state is approximately equal to the F number in the close-up observation state, so that there is no necessity that the F number in the normal observation state is reduced more than necessary even though the F number in the close-up observation state is reduced so as not to be affected by diffraction.

Besides, if Fno_(u)/Fno_(c) is below the lower limit of the condition (19), the F number in the normal observation state easily becomes small more than necessary when the F number in the close-up observation state is reduced up to diffraction limit.

Also, it is preferred that: the objective optical system of the present embodiment consists of five lens groups; the second lens group from the object side of the five lens groups is the magnification-changing group; and the fourth lens group from the object side of the five lens groups is the focusing group.

Such a constitution of the optical system of the present embodiment makes it easy to perform highly accurate focusing while variations in field curvature and in chromatic aberration of magnification are small with respect to particular objects to be imaged. Particularly, the objective optical system having this constitution is very suitable to be used as an objective optical system for endoscopes or the like.

Also, an observation apparatus of an embodiment according to the present invention is characterized in that the observation apparatus is provided with one of the above-described objective optical systems and an autofocus mechanism for moving the focusing group.

Besides, for example, the autofocus mechanism is composed of: a drive mechanism which moves the focusing group along the optical axis; and a control means which controls the drive mechanism on the basis of predetermined information (information on images formed on an image pickup element in the case where the image pickup element like CCD is arranged on the image side of the objective optical system, information on a distance between the top of the objective optical system and an object to be observed, and so on).

Embodied Examples according to the embodiments of the objective optical systems of the present invention respectively are explained while reference to the drawings is being made, below.

Besides, subscript numbers given to r₁, r₂, . . . and d₁, d₂, . . . in the sectional views along the optical axes of the respective optical systems correspond to surface numbers 1, 2, . . . in numerical data, respectively.

Also, in the numerical data, s denotes surface number, r denotes radius of curvature of is each surface, d denotes surface distance, nd denotes refractive index at the d line, and vd denotes Abbe's number at the d line.

Embodied Example 1

An observation apparatus provided with an objective optical system according to Embodied Example 1 is explained in detail using FIGS. 1A-1C, below.

FIGS. 1A to 1C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 1A shows the normal observation state of the optical system (in the farthest point state), FIG. 1B shows the middle state of the optical system (in the farthest point state), and FIG. 1C shows the close-up observation state of the optical system (the farthest point state).

As shown in FIGS. 1A-1C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 1A-1C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power, a second lens group G₂ having negative power and being movable along the optical axis, a third lens group G₃ having positive power, a fourth lens group G₄ having negative power and being movable along the optical axis, and a fifth lens group G₅ having positive power, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having negative power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of a lens L₄₁ that is a biconcave lens having negative power.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; a lens L₅₂ that is a biconcave lens having negative power; and a lens L₅₃ that is a biconvex lens having positive power, these lenses being arranged in that order from the object side. The lens L₅₁ and the lens L₅₂ are joined to each other.

An amount of variation in magnification per movement of the fourth lens group G₄ is smaller than an amount of variation in magnification per movement of the second lens group G₂ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Embodied Example 2

An observation apparatus provided with an objective optical system according to Embodied Example 2 is explained in detail using FIGS. 2A-2C, below.

FIGS. 2A to 2C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 2A shows the normal observation state of the optical system (in the farthest point state), FIG. 2B shows the middle state of the optical system (in the farthest point state), and FIG. 2C shows the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 2A-2C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIG. 2A-2C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power, a second lens group G₂ having negative power and being movable along the optical axis, a third lens group G₃ having positive power, a fourth lens group G₄ having negative power and being movable along the optical axis, and a fifth lens group G₅ having positive power, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a biconcave lens having negative power; a lens L₁₄ that is a biconvex lens having positive power; a lens L₁₅ that is a biconvex lens having positive power; and a lens L₁₆ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₁₅ and the lens L₁₆ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having negative power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of: a lens L₄₁ that is a biconvex lens having positive power; and a lens L₄₂ that is a biconcave lens having negative power, these lenses being arranged in that order from the object side. The lens L₄₁ and the lens L₄₂ are joined to each other.

The fifth lens group G₅ is composed of a lens L₅₁ that is a biconvex lens having positive power.

An amount of variation in magnification per movement of the fourth lens group G₄ is smaller than an amount of variation in magnification per movement of the second lens group G₂ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally is selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Embodied Example 3

An observation apparatus provided with an objective optical system according to Embodied Example 3 is explained in detail using FIGS. 3A-3C and 4A-4L, below.

FIGS. 3A to 3C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 3A shows the normal observation state of the optical system (in the farthest point state), FIG. 3B shows the middle state of the optical system (in the farthest point state), and FIG. 3C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 4A to 4L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 3A-3C. To be specific, FIGS. 4A to 4D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 4E to 4H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 4I to 4L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 3A-3C, this observation apparatus includes: an optical system which includes an objective optical system OL, a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power, and a CCD cover glass CG; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 3A-3C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having negative power, a second lens group G₂ having positive power and being movable along the optical axis, a third lens group G₃ having negative power and being movable along the optical axis, and a fourth lens group G₄ having positive power, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the second lens group G₂ and the third lens group G₃ in such a way that the aperture stop S moves integrally with the third lens group G₃.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power and with a concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a biconcave lens having negative power; and a lens L₁₄ that is a biconvex lens having positive power, these lenses being arranged in that order from the object side.

The second lens group G₂ is composed of: a lens L₂₁ that is a biconvex lens having positive power; and a lens L₂₂ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of: a lens L₃₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₃₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₃₁ and the lens L₃₂ are joined to each other.

The fourth lens group G₄ is composed of: a lens L₄₁ that is a biconvex lens having positive power; a lens L₄₂ that is a biconvex lens having positive power; and a lens L₄₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₄₂ and the lens L₄₃ are joined to each other.

An amount of variation in magnification per movement of the third lens group G₃ is is larger than an amount of variation in magnification per movement of the second lens group G₂ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the third lens group G₃ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the third lens group G₃ but also the second lens group G₂ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 1

Unit: mm Surface data Radius Surface Refractive Surface No. of curvature distance index Abbe's number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 0.996 0.82  3 ∞ 0.31 1.51400 75.00  4 ∞ 0.37  5 −6.212 0.60 1.51742 52.43  6 7.399 0.24  7 20.660 1.09 1.51633 64.14  8 −1.988 D8  9 5.439 0.90 1.77250 49.60 10 −3.566 0.31 1.92286 18.90 11 −8.344 D11 12 (Stop surface) ∞ 0.03 13 ∞ 0.28 1.48749 70.23 14 1.200 0.32 1.59270 35.31 15 1.542 D15 16 2.648 1.45 1.48749 70.23 17 −11.997 0.16 18 2.523 1.47 1.48749 70.23 19 −1.897 0.40 1.92286 18.90 20 −4.420 0.15 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.50 23 ∞ 1.60 1.51633 64.14 24 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.38 Focal length 0.95 1.14 1.31 1.35 F number 5.26 5.52 5.40 5.31 Angle of view 142.41 97.88 71.18 67.90 (2ω) Image height 0.85 0.85 0.85 0.85 Lens total 13.48 13.24 12.83 12.74 length (in air) BF (in air) 1.90 1.66 1.25 1.16 Surface distance D8 0.50 0.50 0.50 0.35 D11 0.35 1.04 1.81 1.96 D15 1.63 0.93 0.16 0.16 Data on lens groups Group The first surface of lens group Focal length 1 1 −5.10 2 9 4.91 3 13 −3.45 4 16 2.87 Data on conditions Condition (1): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 10: 6.934 Condition (2): 1 < m_(c-n)/m_(c-d) < 1.55: 1.0908 Condition (3): 0.2 < |(1 − β₁ · β₁) × β₁′ · β₁′| < 3: 0.31678 Condition (4): 2 < |F₁/F_(c-d)| < 8: 3.735383 Condition (5): 1.8 < |F₂/F_(c-d)| < 5: 2.625099 Condition (6): 0.02 < D₁/L < 0.12: 0.049542191 Condition (7): |DT_(c-n) − DT_(c-d)| < 5: 1.5262 Condition (8): DT_(u-d) < −50: −67.921 Condition (9): Fno_(u)/Fno_(c) > 0.94: 0.974

Embodied Example 4

An observation apparatus provided with an objective optical system according to Embodied Example 4 is explained in detail using FIGS. 5A-5C and 6A-6L, below.

FIG. 5A to 5C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 5A shows the normal observation state of the optical system (in the farthest point state), FIG. 5B shows the middle state of the optical system (in the farthest point state), and FIG. 5C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 6A to 6L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIG. 5A-5C. To be specific, FIGS. 6A to 6D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 6E to 6H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 6I to 6L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 5A-5C, this observation apparatus includes: an optical system which includes an objective optical system OL, a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power, and a CCD cover glass CG; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 5A-5C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having negative power, a second lens group G₂ having positive power and being movable along the optical axis, a third lens group G₃ having positive power, a fourth lens group G₄ having negative power and being movable along the optical axis, and a fifth lens group G₅ having positive power, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the third lens group G₃ and the fourth lens group G₄ in such a way that the aperture stop S moves integrally with the fourth lens group G₄.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; and a lens L₁₃ that is a meniscus lens having negative power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side.

The second lens group G₂ is composed of a lens L₂₁ that is a meniscus lens having positive power with the convex surface thereof facing the image side.

The third lens group G₃ is composed of: a lens L₃₁ that is a biconvex lens having positive power; and a lens L₃₂ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₃₁ and the lens L₃₂ are joined to each other.

The fourth lens group G₄ is composed of: a lens L₄₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₄₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₄₁ and the lens L₄₂ are joined to each other.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; a lens L₅₂ that is a biconvex lens having positive power; and a lens L₅₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₅₂ and the lens L₅₃ are joined to each other.

An amount of variation in magnification per movement of the fourth lens group G₄ is larger than an amount of variation in magnification per movement of the second lens group G₂ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the fourth lens group G₄ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the fourth lens group G₄ but also the second lens group G₂ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 2

Unit: mm Surface data Radius Surface Refractive Surface No. of curvature distance index Abbe's number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.077 0.82  3 ∞ 0.31 1.51400 74.00  4 ∞ 0.28  5 8.349 0.60 1.51742 52.43  6 3.733 D6  7 −10.468 1.00 1.51633 64.14  8 −1.987 D8  9 6.230 0.90 1.77250 49.60 10 −2.754 0.31 1.92286 18.90 11 −6.114 D11 12 (Stop surface) ∞ 0.03 13 ∞ 0.28 1.48749 70.23 14 0.733 0.32 1.59270 35.31 15 1.228 D15 16 2.477 1.45 1.48749 70.23 17 −8.708 0.16 18 2.204 1.47 1.48749 70.23 19 −1.833 0.40 1.92286 18.90 20 −6.842 0.15 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.50 23 ∞ 1.60 1.51633 64.14 24 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.39 Focal length 0.95 1.23 1.33 1.28 F number 5.10 5.48 5.40 5.22 Angle of view 142.45 82.85 69.54 69.30 (2ω) Image height 0.85 0.85 0.85 0.85 Lens total 13.39 13.05 12.81 12.66 length (in air) BF (in air) 1.91 1.57 1.33 1.18 Surface distance D6 0.60 0.60 0.60 0.69 D8 0.50 0.50 0.50 0.41 D11 0.15 1.11 1.51 1.51 D15 1.54 0.58 0.18 0.18 Data on lens groups Group The first surface of lens group Focal length 1 1 −0.98 2 7 4.57 3 9 4.71 4 13 −3.07 5 16 2.73 Data on conditions Condition (1): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 10: 5.9922 Condition (2): 1 < m_(c-n)/m_(c-d) < 1.55: 1.2815 Condition (3): 0.2 < |(1 − β₁ · β₁) × β₁′ · β₁′| < 3: 2.2482 Condition (4): 2 < |F₁/F_(c-d)| < 8: 3.439532 Condition (5): 1.8 < |F₂/F_(c-d)| < 5: 2.316437 Condition (6): 0.02 < D₁/L < 0.12: 0.077846103 Condition (7): |DT_(c-n) − DT_(c-d)| < 5: 1.8351 Condition (8): DT_(u-d) < −50: −68.2131 Condition (9): Fno_(u)/Fno_(c) > 0.94: 0.944721

Embodied Example 5

An observation apparatus provided with an objective optical system according to Embodied Example 5 is explained in detail using FIGS. 7A-7C and 8A-8L, below.

FIGS. 7A to 7C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 7A shows the normal observation state of the optical system (in the farthest point state), FIG. 7B shows the middle state of the optical system (in the farthest point state), and FIG. 7C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 8A to 8L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 7A-7C. To be specific, FIGS. 8A to 8D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 8E to 8H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 8I to 8L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 7A-7C, this observation apparatus includes: an optical system which includes an objective optical system OL, a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power, and a CCD cover glass CG; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 7A-7C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having negative power, a second lens group G₂ having negative power and being movable along the optical axis, a third lens group G₃ having positive power, a fourth lens group G₄ having negative power and being movable along the optical axis, and a fifth lens group G₅ having positive power, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the third lens group G₃ and the fourth lens group G₄ in such a way that the aperture stop S moves integrally with the fourth lens group G₄.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; and a lens L₁₃ that is a meniscus lens having positive power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side.

The second lens group G₂ is composed of a lens L₂₁ that is a meniscus lens having negative power with the convex surface thereof facing the image side.

The third lens group G₃ is composed of: a lens L₃₁ that is a biconvex lens having positive power; and a lens L₃₂ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₃₁ and the lens L₃₂ are joined to each other.

The fourth lens group G₄ is composed of: a lens L₄₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₄₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₄₁ and the lens L₄₂ are joined to each other.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a meniscus lens having positive power with the concave surface thereof facing the image side; a lens L₅₂ that is a biconvex lens having positive power; and a lens L₅₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₅₂ and the lens L₅₃ are joined to each other.

An amount of variation in magnification per movement of the fourth lens group G₄ is larger than an amount of variation in magnification per movement of the second lens group G₂ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the fourth lens group G₄ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the fourth lens group G₄ but also the second lens group G₂ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 3

Unit: mm Surface data Radius Surface Refractive Surface No. of curvature distance index Abbe's number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.219 0.82  3 ∞ 0.31 1.51400 73.43  4 ∞ 1.07  5 −3.199 0.60 1.51742 52.43  6 −1.762 D6  7 −1.500 0.30 1.51633 64.14  8 −2.732 D8  9 5.195 0.90 1.77250 49.60 10 −2.090 0.31 1.92286 18.90 11 −3.497 D11 12 (Stop surface) ∞ 0.03 13 ∞ 0.28 1.48749 70.23 14 1.200 0.32 1.59270 35.31 15 1.783 D15 16 2.734 1.45 1.48749 70.23 17 44.661 0.16 18 2.074 1.47 1.48749 70.23 19 −1.828 0.40 1.92286 18.90 20 −4.725 0.15 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.50 23 ∞ 1.60 1.51633 64.14 24 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.27 Focal length 0.95 1.08 1.21 1.17 F number 5.41 5.53 5.40 5.26 Angle of view 142.66 106.19 82.40 83.45 (2ω) Image height 0.85 0.85 0.85 0.85 Lens total 13.38 13.18 12.88 12.75 length (in air) BF (in air) 1.90 1.70 1.40 1.27 Surface distance D6 0.70 0.70 0.70 0.48 D8 0.35 0.35 0.35 0.57 D11 0.15 0.79 1.49 1.49 D15 1.50 0.86 0.16 0.16 Data on lens groups Group The first surface of lens group Focal length 1 1 −3.83 2 7 −7.02 3 9 3.10 4 13 −4.18 5 16 3.05 Data on conditions Condition (1): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 10: 5.1835 Condition (2): 1 < m_(c-n)/m_(c-d) < 1.55: 1.2673 Condition (3): 0.2 < |(1 − β₁ · β₁) × β₁′ · β₁′| < 3: 0.78613 Condition (4): 2 < |F₁/F_(c-d)| < 8: 5.825520 Condition (5): 1.8 < |F₂/F_(c-d)| < 5: 3.470654 Condition (6): 0.02 < D₁/L < 0.12: 0.074314407 Condition (7): |DT_(c-n) − DT_(c-d)| < 5: 1.9309 Condition (8): DT_(u-d) < −50: −68.0189 Condition (9): Fno_(u)/Fno_(c) > 0.94: 1.00249

Embodied Example 6

An observation apparatus provided with an objective optical system according to Embodied Example 6 is explained in detail using FIGS. 9A-9C and 10A-10L, below.

FIGS. 9A to 9C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 9A shows the normal observation state of the optical system (in the farthest point state), FIG. 9B shows the middle state of the optical system (in the farthest point state), and FIG. 9C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 10A to 10L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 9A-9C. To be specific, FIGS. 10A to 10D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 10E to 10H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 10I to 10L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 9A-9C, this observation apparatus includes: an optical system which includes an objective optical system OL, a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power, and a CCD cover glass CG; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 9A-9C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having negative power, a second lens group G₂ having positive power and being movable along the optical axis, a third lens group G₃ having positive power, a fourth lens group G₄ having negative power and being movable along the optical axis, and a fifth lens group G₅ having positive power, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the third lens group G₃ and the fourth lens group G₄ in such a way that the aperture stop S moves integrally with the fourth lens group G₄.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₁₂ that is a plano lens, these lenses being arranged in that order from the object side.

The second lens group G₂ is composed of a lens L₂₁ that is a meniscus lens having positive power with the convex surface thereof facing the image side.

The third lens group G₃ is composed of: a lens L₃₁ that is a meniscus lens having negative power with the convex surface thereof facing the image side; a lens L₃₂ that is a biconvex lens having positive power; and a lens L₃₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₃₂ and the lens L₃₃ are joined to each other.

The fourth lens group G₄ is composed of: a lens L₄₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₄₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₄₁ and the lens L₄₂ are joined to each other.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; a lens L₅₂ that is a biconvex lens having positive power; and a lens L₅₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₅₂ and the lens L₅₃ are joined to each other.

An amount of variation in magnification per movement of the fourth lens group G₄ is larger than an amount of variation in magnification per movement of the second lens group G₂ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the fourth lens group G₄ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the fourth lens group G₄ but also the second lens group G₂ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 4

Unit: mm Surface data Radius Surface Refractive Surface No. of curvature distance index Abbe's number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.088 0.82  3 ∞ 0.31 1.51400 74.00  4 ∞ D4  5 −3.668 0.60 1.51742 52.43  6 −1.774 D6  7 −1.496 1.00 1.51633 64.14  8 −2.261 0.25  9 8.267 0.90 1.77250 49.60 10 −2.222 0.31 1.92286 18.90 11 −3.851 D11 12 (Stop surface) ∞ 0.03 13 ∞ 0.28 1.48749 70.23 14 1.100 0.32 1.59270 35.31 15 1.755 D15 16 2.669 1.45 1.48749 70.23 17 −17.036 0.16 18 2.312 1.47 1.48749 70.23 19 −2.147 0.40 1.92286 18.90 20 −9.061 0.17 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.50 23 ∞ 1.60 1.51633 64.14 24 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.30 Focal length 0.94 1.09 1.23 1.21 F number 5.41 5.56 5.40 5.35 Angle of view 142.68 102.64 77.54 77.57 (2ω) Image height 0.85 0.85 0.85 0.85 Lens total 13.38 13.17 12.83 12.78 length (in air) BF (in air) 1.92 1.70 1.36 1.32 Surface distance D4 0.53 0.53 0.53 0.58 D6 0.40 0.40 0.40 0.35 D11 0.15 0.90 1.72 1.72 D15 1.72 0.98 0.16 0.16 Data on lens groups Group The first surface of lens group Focal length 1 1 −1.23 2 5 5.99 3 7 3.82 4 13 −4.25 5 16 3.09 Data on conditions Condition (1): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 10: 6.5641 Condition (2): 1 < m_(c-n)/m_(c-d) < 1.55: 1.0775 Condition (3): 0.2 < |(1 − β₁ · β₁) × β₁′ · β₁′| < 3: 1.06971 Condition (4): 2 < |F₁/F_(c-d)| < 8: 4.885378 Condition (5): 1.8 < |F₂/F_(c-d)| < 5: 3.460754 Condition (6): 0.02 < D₁/L < 0.12: 0.056617 Condition (7): |DT_(c-n) − DT_(c-d)| < 5: 0.63327 Condition (8): DT_(u-d) < −50: −67.9783 Condition (9): Fno_(u)/Fno_(c) > 0.94: 1.00166

Embodied Example 7

An observation apparatus provided with an objective optical system according to Embodied Example 7 is explained in detail using FIGS. 11A-11C and 12A-12L, below.

FIGS. 11A to 11C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 11A shows the normal observation state of the optical system (in the farthest point state), FIG. 11B shows the middle state of the optical system (in the farthest point state), and FIG. 11C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 12A to 12L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 11A-11D. To be specific, FIGS. 12A to 12D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 12E to 12H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 12I to 12L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIG. 11A-11C, this observation apparatus includes: an optical system which includes an objective optical system OL, a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power, and a CCD cover glass CG; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 11A-11C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having negative power, a second lens group G₂ having negative power and being movable along the optical axis, a third lens group G₃ having positive power, a fourth lens group G₄ having negative power and being movable along the optical axis, and a fifth lens group G₅ having positive power, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the third lens group G₃ and the fourth lens group G₄ in such a way that the aperture stop S moves integrally with the fourth lens group G₄.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₁₂ that is a plano lens, these lenses being arranged in that order from the object side.

The second lens group G₂ is composed of a lens L₂₁ that is a meniscus lens having negative power with the concave surface thereof facing the image side.

The third lens group G₃ is composed of: a lens L₃₁ that is a biconvex lens having positive power; a lens L₃₂ that is a biconvex lens having positive power; and a lens L₃₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₃₂ and the lens L₃₃ are joined to each other.

The fourth lens group G₄ is composed of: a lens L₄₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₄₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₄₁ and the lens L₄₂ are joined to each other.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; a lens L₅₂ that is a biconvex lens having positive power; and a lens L₅₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₅₂ and the lens L₅₃ are joined to each other.

An amount of variation in magnification per movement of the fourth lens group G₄ is larger than an amount of variation in magnification per movement of the second lens group G₂ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the fourth lens group G₄ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the fourth lens group G₄ but also the second lens group G₂ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 5

Unit: mm Surface data Radius Surface Refractive Surface No. of curvature distance index Abbe's number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.102 0.82  3 ∞ 0.31 1.51400 74.00  4 ∞ D4  5 8.210 0.60 1.51742 52.43  6 2.334 D6  7 6.426 1.00 1.51633 64.14  8 −3.085 0.25  9 99.199 0.90 1.77250 49.60 10 −2.013 0.31 1.92286 18.90 11 −3.076 D11 12 (Stop surface) ∞ 0.03 13 ∞ 0.28 1.48749 70.23 14 1.100 0.32 1.59270 35.31 15 1.743 D15 16 2.558 1.45 1.48749 70.23 17 −16.397 0.16 18 2.293 1.47 1.48749 70.23 19 −2.029 0.40 1.92286 18.90 20 −10.233 0.15 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.50 23 ∞ 1.60 1.51633 64.14 24 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.30 Focal length 0.94 1.09 1.23 1.22 F number 5.40 5.57 5.40 5.35 Angle of view 142.71 101.70 76.57 76.20 (2ω) Image height 0.85 0.85 0.85 0.85 Lens total 13.38 13.17 12.82 12.78 length (in air) BF (in air) 1.90 1.69 1.34 1.30 Surface distance D4 0.53 0.53 0.53 0.50 D6 0.40 0.40 0.40 0.43 D11 0.15 0.91 1.73 1.73 D15 1.74 0.98 0.16 0.16 Data on lens groups Group The first surface of lens group Focal length 1 1 −1.25 2 5 −6.53 3 7 2.45 4 13 −4.20 5 16 3.08 Data on conditions Condition (1): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 10: 6.66717 Condition (2): 1 < m_(c-n)/m_(c-d) < 1.55: 1.0699 Condition (3): 0.2 < |(1 − β₁ · β₁) × β₁′ · β₁′| < 3: 1.515007 Condition (4): 2 < |F₁/F_(c-d)| < 8: 5.316049 Condition (5): 1.8 < |F₂/F_(c-d)| < 5: 3.422266 Condition (6): 0.02 < D₁/L < 0.12: 0.056617 Condition (7): |DT_(c-n) − DT_(c-d)| < 5: 0.70351 Condition (8): DT_(u-d) < −50: −67.9774 Condition (9): Fno_(u)/Fno_(c) > 0.94: 1.000205

Embodied Example 8

An observation apparatus provided with an objective optical system according to Embodied Example 8 is explained in detail using FIGS. 13A-13C and 14A-14L, below.

FIGS. 13A to 13C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 13A shows the normal observation state of the optical system (in the farthest point state), FIG. 13B shows the middle state of the optical system (in the farthest point state), and FIG. 13C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 14A to 14L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 13A-13C. To be specific, FIGS. 14A to 14D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 14E to 14H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 14I to 14L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 13A-13C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 13A-13C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having negative power, a second lens group G₂ having positive power and being movable along the optical axis, a third lens group G₃ having positive power, a fourth lens group G₄ having negative power and being movable along the optical axis, and a fifth lens group G₅ having positive power, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the third lens group G₃ and the fourth lens group G₄ in such a way that the aperture stop S moves integrally with the fourth lens group G₄.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; and a lens L₁₃ that is a biconcave lens having negative power, these lenses being arranged in that order from the object side.

The second lens group G₂ is composed of a lens L₂₁ that is a biconvex lens having positive power.

The third lens group G₃ is composed of: a lens L₃₁ that is a biconvex lens having positive power; and a lens L₃₂ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₃₁ and the lens L₃₂ are joined to each other.

The fourth lens group G₄ is composed of: a lens L₄₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₄₂ that is a meniscus lens having negative power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₄₁ and the lens L₄₂ are joined to each other.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; a lens L₅₂ that is a biconvex lens having positive power; a lens L₅₃ that is a biconcave lens having negative power; and a lens L₅₄ that is a biconvex lens having positive power, these lenses being arranged in that order from the object side. The lens L₅₂ and the lens L₅₃ are joined to each other.

An amount of variation in magnification per movement of the fourth lens group G₄ is larger than an amount of variation in magnification per movement of the second lens group G₂ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the fourth lens group G₄ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the fourth lens group G₄ but also the second lens group G₂ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 6

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.28 1.88300 40.76  2 0.844 0.47  3 ∞ 0.31 1.51400 74.00  4 ∞ 0.28  5 −2.357 0.38 1.60342 38.03  6 223.221 D6  7 51.662 0.57 1.51633 64.14  8 −2.800 D8  9 4.119 0.71 1.75520 27.51 10 −1.027 0.36 1.92286 18.90 11 −2.339 D11 12 (Stop surface) ∞ 0.02 13 ∞ 0.28 1.48749 70.23 14 1.742 0.50 1.59270 35.31 15 1.256 D15 16 1.789 0.69 1.48749 70.23 17 −3.243 0.11 18 3.759 0.63 1.48749 70.23 19 −3.178 0.36 1.92286 18.90 20 4.753 1.31 21 3.283 0.69 1.58313 59.38 22 −7.262 0.30 23 ∞ 0.40 1.52300 58.50 24 ∞ 0.20 25 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.09 Focal length 0.88 0.92 0.96 0.95 F number 5.08 5.10 5.07 5.03 Angle of view 147.14 129.01 115.33 115.72 (2ω) Image height 0.85 0.85 0.85 0.85 Lens total 10.46 10.30 10.12 10.05 length (in air) BF (in air) 0.69 0.54 0.35 0.28 Surface distance D6 0.87 0.87 0.87 0.91 D8 0.25 0.25 0.25 0.20 D11 0.20 0.35 0.52 0.52 D15 0.51 0.36 0.20 0.20 Data on lens groups The first surface Group of lens group Focal length 1 1 −0.64 2 7 5.16 3 9 2.53 4 13 −2.49 5 16 2.94 Data on conditions Condition (1): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 10: 4.61297 Condition (2): 1 < m_(c-n)/m_(c-d) < 1.55: 1.1953 Condition (3): 0.2 < |(1 − β₁ · β₁) × β₁′ · β₁′| < 3: 1.9016 Condition (4): 2 < |F₁/F_(c-d)| < 8: 5.101347822 Condition (5): 1.8 < |F₂/F_(c-d)| < 5: 2.59931 Condition (6): 0.02 < D₁/L < 0.12: 0.100967389 Condition (7): |DT_(c-n) − DT_(c-d)| < 5: 2.08875 Condition (8): DT_(u-d) < −50: −70.0075 Condition (9): Fno_(u)/Fno_(c) > 0.94: 1.00279

Embodied Example 9

An observation apparatus provided with an objective optical system according to Embodied Example 9 is explained in detail using FIGS. 15A-15C and 16A-16L, below.

FIGS. 15A to 15C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 15A shows the normal observation state of the optical system (in the farthest point state), FIG. 15B shows the middle state of the optical system (in the farthest point state), and FIG. 15C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 16A to 16L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 15A-15C. To be specific, FIGS. 16A to 16D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 16E to 16H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 16I to 16L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 15A-15C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 15A-15C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, a fourth lens group G₄ that is a focusing group having negative power and being moved along the optical axis at least in focusing, and a fifth lens group G₅ having positive power and being immovable in magnification change and in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side; and a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order is from the object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of: a lens L₃₁ that is a meniscus lens having positive power with the concave surface thereof facing the image side; and a lens L₃₂ that is a plano-convex lens having positive power with the planar surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₃₁ and the lens L₃₂ are joined to each other.

The fourth lens group G₄ is composed of a lens L₄₁ that is a plano-concave lens having negative power with the planar surface thereof facing the image side.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; a lens L₅₂ that is a biconcave lens having negative power; and a lens L₅₃ that is a biconvex lens having positive power, these lenses being arranged in that order from the object side. The lens L₅₁ and the lens L₅₂ are joined to each other.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 7

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.399 0.82  3 ∞ 0.31 1.51400 73.43  4 ∞ 2.35  5 −2.625 2.19 1.80518 25.42  6 −3.543 0.45  7 4.856 0.58 1.77250 49.60  8 −3.173 0.31 1.92286 18.90  9 −9.570 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 1.604 0.50 1.59270 35.31 13 2.024 D13 14 3.170 0.38 1.72916 54.68 15 3.902 0.60 1.83481 42.71 16 ∞ D16 17 −11.197 0.30 1.69680 55.53 18 ∞ D18 19 3.397 1.01 1.48749 70.23 20 −2.500 0.40 1.92286 18.90 21 18.034 0.45 22 2.784 1.00 1.51633 64.14 23 −9.018 0.45 24 ∞ 0.40 1.52300 58.50 25 ∞ 0.45 26 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.21 Focal length 0.95 1.08 1.15 1.15 F number 4.35 4.54 4.61 4.61 Angle of view 144.13 111.20 99.28 99.15 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 17.31 17.11 16.96 16.91 (in air) BF (in air) 1.11 0.91 0.76 0.71 Surface distance D9 0.45 1.04 1.37 1.37 D13 1.84 1.24 0.91 0.91 D16 0.80 0.80 0.80 0.95 D18 0.80 0.80 0.80 0.65 Data on lens groups The first surface Group of lens group Focal length 1 1 1.55 2 11 −4.51 3 14 3.89 4 17 −16.00 5 19 6.26 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 5.915 Condition (11): |ΔDT_(f)| < 2: 0.1583 Condition (12): 0.2 < |(1 − β_(f) · β_(f)) × β_(f)′ · β_(f)′| < 0.9: 0.3548 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.134 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 3.545 Condition (15): |γ| < 11.5: 8.860 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 1.470 Condition (17): DT_(u-d) < −50: −62.34 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 13.90 Condition (19): 0.83 < Fno_(u)/Fno_(c): 0.943

Embodied Example 10

An observation apparatus provided with an objective optical system according to Embodied Example 10 is explained in detail using FIGS. 17A-17C and 18A-18L, below.

FIGS. 17A to 17C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 17A shows the normal observation state of the optical system (in the farthest point state), FIG. 17B shows the middle state of the optical system (in the farthest point state), and FIG. 17C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 18A to 18L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 17A-17C. To be specific, FIGS. 18A to 18D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 18E to 18H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 18I to 18L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 17A-17C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 17A-17C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, a fourth lens group G₄ that is a focusing group having negative power and being moved along the optical axis at least in focusing, and a fifth lens group G₅ having positive power and being immovable in magnification change and in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of a lens L₄₁ that is a plano-concave lens having negative power with the planar surface thereof facing the image side.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; and a lens L₅₂ that is a biconcave lens having negative power, these lenses being arranged in that order from the object side. The lens L₅₁ and the lens L₅₂ are joined to each other.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 8

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.150 0.92  3 ∞ 0.31 1.51400 73.43  4 ∞ 1.61  5 −2.474 0.92 2.00330 28.27  6 −2.550 0.30  7 5.716 0.49 1.77250 49.60  8 −2.164 0.31 1.92286 18.90  9 −4.682 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 1.563 0.31 1.59270 35.31 13 1.620 D13 14 3.341 0.64 1.72916 54.68 15 −5.776 D15 16 −12.502 0.30 1.92286 20.88 17 ∞ D17 18 1.940 1.21 1.48749 70.23 19 −1.866 0.30 1.92286 18.90 20 12.584 0.44 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.44 23 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.30 Focal length 0.91 1.07 1.19 1.14 F number 6.95 7.22 7.01 6.72 Angle of view 145.49 99.99 76.74 76.64 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 13.30 13.09 12.77 12.63 (in air) BF (in air) 1.08 0.87 0.56 0.42 Surface distance D9 0.30 0.99 1.65 1.65 D13 2.03 1.33 0.68 0.68 D15 0.80 0.80 0.80 1.28 D17 0.80 0.80 0.80 0.32 Data on lens groups The first surface Group of lens group Focal length 1 1 1.52 2 11 −3.39 3 14 2.98 4 16 −13.40 5 18 244.00 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 5.499 Condition (11): |ΔDT_(f)| < 2: 1.407 Condition (12): 0.2 < |(1 − β_(f) · β_(f)) × β_(f)′ · β_(f)′| < 0.9: 0.4301 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.28 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 3.946 Condition (15): |γ| < 11.5: 9.450 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 2.003 Condition (17): DT_(u-d) < −50: −61.39 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 11.29 Condition (19): 0.83 < Fno_(u)/Fno_(c): 0.991

Embodied Example 11

An observation apparatus provided with an objective optical system according to Embodied Example 11 is explained in detail using FIGS. 19A-19C and 20A-20L, below.

FIGS. 19A to 19C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 19A shows the normal observation state of the optical system (in the farthest point state), FIG. 19B shows the middle state of the optical system (in the farthest point state), and FIG. 19C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 20A to 20L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 19A-19C. To be specific, FIGS. 20A to 20D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 20E to 20H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 20I to 20L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 19A-19C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 19A-19C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, a fourth lens group G₄ that is a focusing group having negative power and being moved along the optical axis at least in focusing, and a fifth lens group G₅ having positive power and being immovable in magnification change and in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of: a lens L₄₁ that is a meniscus lens having positive power with the convex surface thereof facing the image side; and a lens L₄₂ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₄₁ and the lens L₄₂ are joined to each other.

The fifth lens group G₅ is composed of a lens L₅₁ that is a biconvex lens having positive power.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a is plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 9

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.063 0.82  3 ∞ 0.31 1.51400 73.43  4 ∞ 0.89  5 −2.353 1.49 1.80518 25.42  6 −2.463 0.74  7 8.957 0.77 1.77250 49.60  8 −2.138 0.31 1.92286 18.90  9 −4.723 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 1.463 0.50 1.59270 35.31 13 2.056 D13 14 4.429 0.66 1.83481 42.71 15 −6.974 D15 16 −162.911 0.96 1.48749 70.23 17 −2.000 0.35 1.92286 18.90 18 −9.642 D18 19 16.123 0.85 1.51633 64.14 20 −3.355 0.76 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.76 23 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.47 Focal length 0.93 1.15 1.38 1.36 F number 3.93 4.24 4.32 4.25 Angle of view 144.87 98.13 72.72 72.15 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 15.30 15.06 14.63 14.48 (in air) BF (in air) 1.73 1.48 1.06 0.91 Surface distance D9 0.40 1.42 2.44 2.44 D13 2.44 1.43 0.40 0.40 D15 0.70 0.70 0.70 1.00 D18 0.70 0.70 0.70 0.40 Data on lens groups The first surface Group of lens group Focal length 1 1 1.92 2 11 −4.76 3 14 3.32 4 16 −8.00 5 19 5.44 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 6.441 Condition (11): |ΔDT_(f)| < 2: 0.3682 Condition (12): 0.2 < |(1 − β_(f) · β_(f)) × β_(f)′ · β_(f)′| < 0.9: 0.5983 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.227 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 1.680 Condition (15): |γ| < 11.5: 11.46 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 1.851 Condition (17): DT_(u-d) < −50: −61.54 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 5.812 Condition (19): 0.83 < Fno_(u)/Fno_(c): 0.9111

Embodied Example 12

An observation apparatus provided with an objective optical system according to Embodied Example 12 is explained in detail using FIGS. 21A-21C and 22A-22L, below.

FIGS. 21A to 21C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 21A shows the normal observation state of the optical system (in the farthest point state), FIG. 21B shows the middle state of the optical system (in the farthest point state), and FIG. 21C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 22A to 22L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 21A-21C. To be specific, FIGS. 22A to 22D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 22E to 22H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 22I to 22L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 21A-21C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 21A-21C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, and a fourth lens group G₄ that is a focusing group having positive power and being moved along the optical axis at least in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having positive power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of: a lens L₃₁ that is a meniscus lens having positive power with the concave surface thereof facing the image side; a lens L₃₂ that is a biconvex lens having positive power; and a lens L₃₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₃₂ and the lens L₃₃ are joined to each other.

The fourth lens group G₄ is composed of a lens L₄₁ that is a meniscus lens having positive power with the concave surface thereof facing the image side.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 10

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.031 0.82  3 ∞ 0.31 1.51400 73.43  4 ∞ 0.89  5 −2.717 1.62 1.80518 25.42  6 −2.629 0.40  7 9.887 0.68 1.77250 49.60  8 −2.020 0.31 1.92286 18.90  9 −4.209 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 1.211 0.50 1.59270 35.31 13 1.774 D13 14 2.675 0.63 1.83481 42.71 15 4.278 0.95 16 4.039 1.50 1.48749 70.23 17 −1.901 0.30 1.92286 18.90 18 −4.356 D18 19 2.465 1.18 1.51633 64.14 20 6.573 D20 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.58 23 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.39 Focal length 0.95 1.13 1.32 1.28 F number 8.13 8.64 8.81 8.54 Angle of view 144.27 102.98 79.09 80.80 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 15.29 15.06 14.68 14.53 (in air) BF (in air) 1.48 1.25 0.87 1.01 Surface distance D9 0.40 1.16 1.95 1.95 D13 1.95 1.19 0.40 0.40 D18 0.70 0.70 0.70 0.40 D20 0.70 0.70 0.70 1.00 Data on lens groups The first surface Group of lens group Focal length 1 1 1.71 2 11 −4.20 3 14 4.61 4 19 6.93 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 5.982 Condition (11): |ΔDT_(f)| < 2: 0.1553 Condition (12)′: 0.2 < (1 − β_(f) · β_(f)) < 0.9: 0.6234 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.262 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 1.65 Condition (15): |γ| < 11.5: 2.079 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 0.9926 Condition (17): DT_(u-d) < −50: −62.34 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 5.253 Condition (19): 0.83 < Fno_(u)/Fno_(c): 0.9232

Embodied Example 13

An observation apparatus provided with an objective optical system according to Embodied Example 13 is explained in detail using FIGS. 23A-23C and 24A-24L, below.

FIGS. 23A to 23C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 23A shows the normal observation state of the optical system (in the farthest point state), FIG. 23B shows the middle state of the optical system (in the farthest point state), and FIG. 23C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 24A to 24L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 23A-23C. To be specific, FIGS. 24A to 24D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 24E to 24H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 24I to 24L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 23A-23C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 23A-23C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ that is a focusing group having positive power and being moved along the optical axis at least in focusing, and a fourth lens group G₄ having positive power and being immovable in magnification change and in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is is a plano lens; a lens L₁₃ that is a meniscus lens having positive power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of: a lens L₄₁ that is a biconvex lens having positive power; a lens L₄₂ that is a meniscus lens having negative power with the convex surface thereof facing the image side; and a lens L₄₃ that is a biconvex lens having positive power, these lenses being arranged in that order from the object side. The lens L₄₁ and the lens L₄₂ are joined to each other.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the third lens group G₃ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the third lens group G₃ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 11

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.084 0.82  3 ∞ 0.31 1.51400 73.43  4 ∞ 1.04  5 −2.279 0.82 1.80518 25.42  6 −1.799 1.08  7 7.901 0.84 1.77250 49.60  8 −1.793 0.30 1.92286 18.90  9 −5.424 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 1.231 0.31 1.59270 35.31 13 1.896 D13 14 7.797 1.06 1.83481 42.71 15 −4.517 D15 16 5.862 1.38 1.48749 70.23 17 −2.000 0.30 1.92286 18.90 18 −354.222 0.40 19 2.857 0.85 1.51633 64.14 20 −4.852 0.40 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.40 23 (Image plane) ∞ Observation state Nomnal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.79 Focal length 0.85 1.15 1.52 1.59 F number 7.39 8.33 8.85 9.23 Angle of view 148.30 95.45 66.49 62.47 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 15.81 15.58 15.09 14.83 (in air) BF (in air) 1.01 0.78 0.29 0.03 Surface distance D9 0.40 1.58 2.80 2.80 D13 3.50 2.33 1.10 0.80 D15 0.70 0.70 0.70 1.00 Data on lens groups The first surface Group of lens group Focal length 1 1 2.09 2 11 −4.50 3 14 3.55 4 16 6.17 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 6.618 Condition (11): |ΔDT_(f)| < 2: 0.5482 Condition (12): 0.2 < |(1 − β_(f) · β_(f)) × β_(f)′ · β_(f)′| < 0.9: 0.5652 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.278 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 0.7875 Condition (15): |γ| < 11.5: 7.211 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 1871 Condition (17): DT_(u-d) < −50: −58.16 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 2.327 Condition (19): 0.83 < Fno_(u)/Fno_(c): 0.8356

Embodied Example 14

An observation apparatus provided with an objective optical system according to Embodied Example 14 is explained in detail using FIGS. 25A-25C and 26A-26L, below.

FIGS. 25A to 25C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 25A shows the normal observation state of the optical system (in the farthest point state), FIG. 25B shows the middle state of the optical system (in the farthest point state), and FIG. 25C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 26A to 26L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 25A-25C. To be specific, FIGS. 26A to 26D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 26E to 26H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 26I to 26L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 25A-25C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 25A-25C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, a fourth lens group G₄ that is a focusing group having negative power and being moved along the optical axis at least in focusing, and a fifth lens group G₅ having positive power and being immovable in magnification change and in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the is object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having negative power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of a lens L₄₁ that is a plano-concave lens having negative power with the planar surface thereof facing the image side.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; and a lens L₅₂ that is a biconcave lens having negative power, these lenses being arranged in that order from the object side. The lens L₅₁ and the lens L₅₂ are joined to each other.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 12

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.150 0.83  3 ∞ 0.31 1.51400 73.43  4 ∞ 1.45  5 −2.223 0.86 2.00330 28.27  6 −2.503 0.30  7 3.728 0.48 1.77250 49.60  8 −2.655 0.31 1.92286 18.90  9 −5.062 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 1.792 0.30 1.59270 35.31 13 1.456 D13 14 3.716 0.83 1.72916 54.68 15 −5.008 D15 16 −9.011 0.30 1.92286 20.88 17 ∞ D17 18 1.892 1.45 1.48749 70.23 19 −1.800 0.30 1.92286 18.90 20 727.658 0.39 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.39 23 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.26 Focal length 0.92 1.05 1.17 1.11 F number 7.25 7.49 7.50 7.14 Angle of view 145.39 109.46 87.76 90.49 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 13.79 13.61 13.33 13.14 (in air) BF (in air) 0.98 0.79 0.50 0.32 Surface distance D9 0.30 0.72 1.16 1.16 D13 2.52 2.10 1.67 1.67 D15 0.80 0.80 0.80 1.30 D17 0.80 0.80 0.80 0.30 Data on lens groups The first surface Group of lens group Focal length 1 1 1.32 2 11 −2.90 3 14 3.03 4 16 −9.66 5 18 13.79 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 4.192 Condition (11): |ΔDT_(f)| < 2: 0.2520 Condition (12): 0.2 < |(1 − β_(f) · β_(f)) × β_(f)′ · β_(f)′| < 0.9: 0.5257 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.413 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 3.332 Condition (15): |γ| < 11.5: 7.232 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 2.384 Condition (17): DT_(u-d) < −50: −61.30 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 8.285 Condition (19): 0.83 < Fno_(u)/Fno_(c): 0.9672

Embodied Example 15

An observation apparatus provided with an objective optical system according to Embodied Example 15 is explained in detail using FIGS. 27A-27C and 28A-28L, below.

FIGS. 27A to 27C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 27A shows the normal observation state of the optical system (in the farthest point state), FIG. 27B shows the middle state of the optical system (in the farthest point state), and FIG. 27C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 28A to 28L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 27A-27C. To be specific, FIGS. 28A to 28D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 28E to 28H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 28I to 28L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 27A-27C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 27A-27C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, a fourth lens group G₄ that is a focusing group having negative power and being moved along the optical axis at least in focusing, and a fifth lens group G₅ having positive power and being immovable in magnification change and in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the is object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having negative power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of: a lens L₄₁ that is a biconvex lens having positive power; and a lens L₄₂ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₄₁ and the lens L₄₂ are joined to each other.

The fifth lens group G₅ is composed of a lens L₅₁ that is a meniscus lens having positive power with the convex surface thereof facing the image side.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 13

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.798 0.82  3 ∞ 0.31 1.51400 73.43  4 ∞ 2.83  5 −2.658 1.23 1.80518 25.42  6 −2.876 0.65  7 5.191 0.86 1.77250 49.60  8 −2.644 0.31 1.92286 18.90  9 −7.720 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 4.217 0.50 1.59270 35.31 13 1.824 D13 14 4.265 0.99 1.83481 42.71 15 −4.935 D15 16 7.318 1.27 1.48749 70.23 17 −1.509 0.30 1.92286 18.90 18 −10.568 D18 19 −4.882 0.46 1.51633 64.14 20 −2.190 0.51 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.51 23 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.82 Focal length 0.92 1.42 1.68 1.61 F number 6.67 8.00 8.04 7.70 Angle of view 145.42 71.84 53.88 54.40 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 16.82 16.45 15.95 15.85 (in air) BF (in air) 1.25 0.88 0.38 0.28 Surface distance D9 0.30 1.83 2.61 2.61 D13 2.66 1.13 0.35 0.35 D15 0.70 0.70 0.70 1.11 D18 0.70 0.70 0.70 0.29 Data on lens groups Group The first surface of lens group Focal length 1 1 1.84 2 11 −3.34 3 14 2.87 4 16 −8.00 5 19 7.24 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 10.59 Condition (11): |ΔDT_(f)| < 2: 1.146 Condition (12): 0.2 < |(1 − β_(f) · β_(f)) × β_(f)′ · β_(f)′| < 0.9: 0.4717 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.153 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 2.392 Condition (15): |γ| < 11.5: 11.63 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 1.251 Condition (17): DT_(u-d) < −50: −61.02 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 4.772 Condition (19): 0.83 < Fno_(u)/Fno_(c): 0.8289

Embodied Example 16

An observation apparatus provided with an objective optical system according to Embodied Example 16 is explained in detail using FIGS. 29A-29C and 30A-30L, below.

FIGS. 29A to 29C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 29A shows the normal observation state of the optical system (in the farthest point state), FIG. 29B shows the middle state of the optical system (in the farthest point state), and FIG. 29C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 30A to 30L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 29A-29C. To be specific, FIGS. 30A to 30D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 30E to 30H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 30I to 30L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 29A-29C, this observation apparatus includes: an optical system including an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 29A-29C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, a fourth lens group G₄ that is a focusing group having negative power and being moved along the optical axis at least in focusing, and a fifth lens group G₅ having positive power and being immovable in magnification change and in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having positive power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the is object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of a lens L₄₁ that is a plano-concave lens having negative power with the planar surface thereof facing the image side.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; and a lens L₅₂ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₅₁ and the lens L₅₂ are joined to each other.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 14

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.120 0.96  3 ∞ 0.31 1.51400 73.43  4 ∞ 1.7   5 −2.793 0.87 2.00330 28.27  6 −2.573 0.30  7 7.502 0.53 1.77250 49.60  8 −2.054 0.31 1.92286 18.90  9 −4.690 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 1.094 0.32 1.59270 35.31 13 1.630 D13 14 3.215 0.68 1.72916 54.68 15 −9.862 D15 16 −12.003 0.30 1.92286 20.88 17 ∞ D17 18 2.178 1.31 1.48749 70.23 19 −1.957 0.30 1.92286 18.90 20 −21.190 0.60 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.60 23 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.38 Focal length 0.94 1.15 1.29 1.28 F number 7.69 8.14 8.01 7.92 Angle of view 143.94 95.04 72.96 72.79 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 14.32 14.05 13.68 13.62 (in air) BF (in air) 1.43 1.16 0.79 0.73 Surface distance D9 0.30 1.19 1.94 1.94 D13 2.44 1.55 0.80 0.80 D15 0.80 0.80 0.80 0.99 D17 0.80 0.80 0.80 0.61 Data on lens groups Group The first surface of lens group Focal length 1 1 1.66 2 11 −3.84 3 14 3.38 4 16 −12.86 5 18 12.97 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 10.42 Condition (11): |ΔDT_(f)| < 2: 1.140 Condition (12): 0.2 < |(1 − β_(f) · β_(f)) × β_(f)′ · β_(f)′| < 0.9: 0.4324 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.104 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 3.351 Condition (15): |γ| < 11.5: 9.450 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 0.7172 Condition (17): DT_(u-d) < −50: −62.59 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 9.948 Condition (19): 0.83 < Fno_(u)/Fno_(c): 0.9603

Embodied Example 17

An observation apparatus provided with an objective optical system according to Embodied Example 17 is explained in detail using FIGS. 31A-31C and 32A-32L, below.

FIGS. 31A to 31C are sectional views taken along the optical axis for showing the structure of the optical system provided for this observation apparatus, where FIG. 31A shows the normal observation state of the optical system (in the farthest point state), FIG. 31B shows the middle state of the optical system (in the farthest point state), and FIG. 31C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 32A to 32L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 31A-31C. To be specific, FIGS. 32A to 32D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 32E to 32H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 32I to 32L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 31A-31C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 31A-31C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, a fourth lens group G₄ that is a focusing group having negative power and being moved along the optical axis at least in focusing, and a fifth lens group G₅ having positive power and being immovable in magnification change and in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the is object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of: a lens L₄₁ that is a meniscus lens having positive power with the convex surface thereof facing the image side; and a lens L₄₂ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₄₁ and the lens L₄₂ are joined to each other.

The fifth lens group G₅ is composed of a lens L₅₁ that is a biconvex lens having positive power.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 15

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.236 0.82  3 ∞ 0.31 1.51400 73.43  4 ∞ 0.93  5 −2.303 1.52 1.80518 25.42  6 −2.341 1.35  7 5.873 0.76 1.77250 49.60  8 −2.294 0.31 1.92286 18.90  9 −7.147 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 1.133 0.50 1.59270 35.31 13 1.832 D13 14 3.484 0.77 1.83481 42.71 15 −8.955 D15 16 −8.878 1.12 1.48749 70.23 17 −1.700 0.30 1.92286 18.90 18 −7.337 D18 19 2.774 0.94 1.51633 64.14 20 −5.223 0.49 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.49 23 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.55 Focal length 0.94 1.20 1.47 1.45 F number 8.37 9.17 9.52 9.40 Angle of view 144.50 96.52 71.88 71.29 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 15.81 15.55 15.12 14.94 (in air) BF (in air) 1.19 0.93 0.50 0.31 Surface distance D9 0.40 1.43 2.39 2.39 D13 2.54 1.51 0.55 0.55 D15 0.70 0.70 0.70 0.99 D18 0.70 0.70 0.70 0.41 Data on lens groups Group The first surface of lens group Focal length 1 1 1.97 2 11 −4.52 3 14 3.07 4 16 −5.30 5 19 3.64 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 7.267 Condition (11): |ΔDT_(f)| < 2: 0.4171 Condition (12): 0.2 < |(1 − β_(f) · β_(f)) × β_(f)′ · β_(f)′| < 0.9: 0.7089 Condition (13): 1 < |m_(c-n)/m_(c-d)|< 2: 1.266 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 1.171 Condition (15): |γ| < 11.5: 14.14 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 2.176 Condition (17): DT_(u-d) < −50: −61.95 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 3.616 Condition (19): 0.83 < Fno_(u)/Fno_(c): 0.8791

Embodied Example 18

An observation apparatus provided with an objective optical system according to Embodied Example 18 is explained in detail using FIGS. 33A-33C and 34A-34L, below.

FIGS. 33A to 33C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 33A shows the normal observation state of the optical system (in the farthest point state), FIG. 33B shows the middle state of the optical system (in the farthest point state), and FIG. 33C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 34A to 34L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 33A-33C. To be specific, FIGS. 34A to 34D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 34E to 34H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 34I to 34L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 33A-33C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 33A-33C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, and a fourth lens group G₄ that is a focusing group having positive power and being moved along the optical axis at least in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the is object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of: a lens L₃₁ that is a biconvex lens having positive power; a lens L₃₂ that is a biconvex lens having positive power; and a lens L₃₃ that is a biconcave lens having negative power, these lenses being arranged in that order from the object side. The lens L₃₂ and the lens L₃₃ are joined to each other.

The fourth lens group G₄ is composed of a lens L₄₁ that is a biconvex lens having positive power.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 16

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.119 0.82  3 ∞ 0.31 1.51400 73.43  4 ∞ 1.01  5 −2.766 1.70 1.80518 25.42  6 −2.774 0.40  7 6.976 0.68 1.77250 49.60  8 −2.077 0.31 1.92286 18.90  9 −4.877 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 1.186 0.50 1.59270 35.31 13 1.702 D13 14 6.544 0.80 1.83481 42.71 15 −5.645 0.50 16 2.820 1.15 1.48749 70.23 17 −7.053 0.39 1.92286 18.90 18 2.554 D18 19 2.451 1.13 1.51633 64.14 20 −3.932 D20 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.40 23 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.39 Focal length 0.94 1.14 1.31 1.28 F number 8.79 9.37 9.52 9.31 Angle of view 144.10 100.51 78.22 78.83 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 14.49 14.24 13.88 13.81 (in air) BF (in air) 1.22 0.97 0.61 0.65 Surface distance D9 0.40 1.19 1.90 1.90 D13 1.90 1.12 0.40 0.40 D18 0.60 0.60 0.60 0.49 D20 0.60 0.60 0.60 0.71 Data on lens groups Group The first surface of lens group Focal length 1 1 1.68 2 11 −4.00 3 14 4.44 4 19 3.10 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 9.000 Condition (11): |ΔDT_(f)| < 2: 0.6486 Condition (12)′: 0.2 < (1 − β_(f) · β_(f)) < 0.9: 0.8099 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.120 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 0.7750 Condition (15): |γ| < 11.5: 2.359 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 0.8418 Condition (17): DT_(u-d) < −50: −62.19 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 2.360 Condition (19): 0.83 < Fno_(u)/Fno_(c): 0.9233

Embodied Example 19

An observation apparatus provided with an objective optical system according to Embodied Example 19 is explained in detail using FIGS. 35A-35C and 36A-36L, below.

FIGS. 35A to 35C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 35A shows the normal observation state of the optical system (in the farthest point state), FIG. 35B shows the middle state of the optical system (in the farthest point state), and FIG. 35C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 36A to 36L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 35A-35C. To be specific, FIGS. 36A to 36D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 36E to 36H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 36I to 36L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 35A-35C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 35A-35C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, a fourth lens group G₄ that is a focusing group having negative power and being moved along the optical axis at least in focusing, and a fifth lens group G₅ having negative power and being immovable in magnification change and in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens is L₂₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of a lens L₄₁ that is a plano-concave lens having negative power with the planar surface thereof facing the image side.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; and a lens L₅₂ that is a biconcave lens having negative power, these lenses being arranged in that order from the object side. The lens L₅₁ and the lens L₅₂ are joined to each other.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 17

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.150 0.92  3 ∞ 0.31 1.51400 73.43  4 ∞ 1.63  5 −2.471 0.92 2.00330 28.27  6 −2.548 0.30  7 5.479 0.49 1.77250 49.60  8 −2.177 0.31 1.92286 18.90  9 −4.829 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 1.541 0.31 1.59270 35.31 13 1.619 D13 14 3.255 0.65 1.72916 54.68 15 −6.145 D15 16 −12.528 0.30 1.92286 20.88 17 ∞ D17 18 1.904 1.22 1.48749 70.23 19 −1.857 0.30 1.92286 18.90 20 9.862 0.42 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.42 23 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.28 Focal length 0.92 1.08 1.18 1.13 F number 9.07 9.35 9.01 8.62 Angle of view 144.60 98.33 76.86 76.78 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 13.32 13.08 12.77 12.64 (in air) BF (in air) 1.06 0.82 0.51 0.38 Surface distance D9 0.30 1.03 1.64 1.64 D13 2.03 1.30 0.69 0.69 D15 0.80 0.80 0.80 1.28 D17 0.80 0.80 0.80 0.32 Data on lens groups Group The first surface of lens group Focal length 1 1 1.51 2 11 −3.40 3 14 2.99 4 16 −13.42 5 18 −166.02 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 7.998 Condition (11): |ΔDT_(f)| < 2: 1.829 Condition (12): 0.2 < |(1 − β_(f) · β_(f)) × β_(f)′ · β_(f)′| < 0.9: 0.4281 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.280 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 3.944 Condition (15): |γ| < 11.5: 9.450 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 2.003 Condition (17): DT_(u-d) < −50: −61.82 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 11.39 Condition (19): 0.83 < Fno_(u)/Fno_(c): 1.005

Embodied Example 20

An observation apparatus provided with an objective optical system according to Embodied Example 20 is explained in detail using FIGS. 37A-37C and 38A-38L, below.

FIGS. 37A to 37C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 37A shows the normal observation state of the optical system (in the farthest point state), FIG. 37B shows the middle state of the optical system (in the farthest point state), and FIG. 37C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 38A to 38L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 37A-37C. To be specific, FIGS. 38A to 38D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 38E to 38H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 38I to 38L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 37A-37C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 37A-37C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, a fourth lens group G₄ that is a focusing group having negative power and being moved along the optical axis at least in focusing, and a fifth lens group G₅ having negative power and being immovable in magnification change and in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens is L₂₂ that is a meniscus lens having positive power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of a lens L₄₁ that is a plano-concave lens having negative power with the planar surface thereof facing the image side.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; and a lens L₅₂ that is a biconcave lens having negative power, these lenses being arranged in that order from the object side. The lens L₅₁ and the lens L₅₂ are joined to each other.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 18

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.150 0.93  3 ∞ 0.31 1.51400 73.43  4 ∞ 1.65  5 −2.477 0.92 2.00330 28.27  6 −2.561 0.30  7 5.396 0.50 1.77250 49.60  8 −2.185 0.31 1.92286 18.90  9 −4.886 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 1.526 0.31 1.59270 35.31 13 1.622 D13 14 3.214 0.64 1.72916 54.68 15 −6.436 D15 16 −13.052 0.30 1.92286 20.88 17 ∞ D17 18 1.900 1.22 1.48749 70.23 19 −1.871 0.30 1.92286 18.90 20 9.099 0.42 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.42 23 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.27 Focal length 0.92 1.08 1.18 1.13 F number 9.11 9.37 9.01 8.67 Angle of view 144.38 98.04 76.93 76.82 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 13.32 13.08 12.77 12.66 (in air) BF (in air) 1.06 0.82 0.52 0.40 Surface distance D9 0.30 1.04 1.64 1.64 D13 2.01 1.28 0.68 0.68 D15 0.80 0.80 0.80 1.23 D17 0.80 0.80 0.80 0.37 Data on lens groups Group The first surface of lens group Focal length 1 1 1.51 2 11 −3.42 3 14 3.01 4 16 −13.99 5 18 −96.86 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 9.073 Condition (11): |ΔDT_(f)| < 2: 1.927 Condition (12): 0.2 < |(1 − β_(f) · β_(f)) × β_(f)′ · β_(f)′| < 0.9: 0.4123 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.244 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 4.087 Condition (15): |γ| < 11.5: 9.450 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 1.767 Condition (17): DT_(u-d) < −50: −62.09 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 11.89 Condition (19): 0.83 < Fno_(u)/Fno_(c): 1.010

Embodied Example 21

An observation apparatus provided with an objective optical system according to Embodied Example 21 is explained in detail using FIGS. 39A-39C and 40A-40L, below.

FIGS. 39A to 39C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 39A shows the normal observation state of the optical system (in the farthest point state), FIG. 39B shows the middle state of the optical system (in the farthest point state), and FIG. 39C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 40A to 40L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 39A-39C. To be specific, FIGS. 40A to 40D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 40E to 40H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 40I to 40L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 39A-39C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 39A-39C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, a fourth lens group G₄ that is a focusing group having negative power and being moved along the optical axis at least in focusing, and a fifth lens group G₅ having positive power and being immovable in magnification change and in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having positive power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of a lens L₂₁ that is a meniscus lens having negative power with the concave surface thereof facing the image side.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of a lens L₄₁ that is a biconcave lens having negative power.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; and a lens L₅₂ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₅₁ and the lens L₅₂ are joined to each other.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 19

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.026 0.71  3 ∞ 0.31 1.51400 73.43  4 ∞ 1.19  5 −3.836 0.90 2.00330 28.27  6 −2.771 0.30  7 5.840 0.49 1.77250 49.60  8 −2.120 0.31 1.92286 18.90  9 −4.469 D9 10 (Stop surface) ∞ 0.03 11 33.913 0.28 1.48749 70.23 12 1.621 D12 13 3.131 0.55 1.72916 54.68 14 −4.154 D14 15 −4.729 0.30 1.92286 20.88 16 2485.252 D16 17 1.824 1.23 1.48749 70.23 18 −2.033 0.30 1.92286 18.90 19 −11.079 0.32 20 ∞ 0.40 1.52300 58.50 21 ∞ 0.32 22 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.26 Focal length 0.93 1.07 1.17 1.14 F number 8.26 8.35 8.00 7.78 Angle of view 144.18 104.39 81.32 80.29 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 11.32 11.09 10.78 10.66 (in air) BF (in air) 0.85 0.62 0.31 0.19 Surface distance D9 0.30 0.90 1.50 1.50 D12 1.50 0.89 0.30 0.30 D14 0.70 0.70 0.70 0.88 D16 0.70 0.70 0.70 0.52 Data on lens groups Group The first surface of lens group Focal length 1 1 1.53 2 11 −3.49 3 13 2.52 4 15 −5.06 5 17 6.17 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 8.128 Condition (11): |ΔDT_(f)| < 2: 1.635 Condition (12): 0.2 < |(1 − β_(f) · β_(f)) × β_(f)′ · β_(f)′| < 0.9: 0.8636 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.240 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 1448 Condition (15): |γ| < 11.5: 14.97 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 2.171 Condition (17): DT_(u-d) < −50: −62.28 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 4.319 Condition (19): 0.83 < Fno_(u)/Fno_(c): 1.031

Embodied Example 22

An observation apparatus provided with an objective optical system according to Embodied Example 22 is explained in detail using FIGS. 41A-41C and 42A-42L, below.

FIGS. 41A to 41C are sectional views taken along the optical axis for showing the configuration of the optical system provided for this observation apparatus, where FIG. 41A shows the normal observation state of the optical system (in the farthest point state), FIG. 41B shows the middle state of the optical system (in the farthest point state), and FIG. 41C shows the close-up observation state of the optical system (in the farthest point state). FIGS. 42A to 42L are aberration diagrams showing spherical aberration, astigmatism, distortion, and chromatic aberration of magnification in the optical system shown in FIGS. 41A-41C. To be specific, FIGS. 42A to 42D show the aberrations in the normal observation state of the optical system (in the farthest point state), FIGS. 42E to 42H show the aberrations in the middle state of the optical system (in the farthest point state), and FIGS. 42I to 42L show the aberrations in the close-up observation state of the optical system (in the farthest point state).

As shown in FIGS. 41A-41C, this observation apparatus includes: an optical system which includes an objective optical system OL and a plano lens PL arranged on the image side of the objective optical system OL and substantially having no refractive power; an aperture stop S arranged in the objective optical system OL; and an image pickup element like CCD for which only its image plane IM is shown in FIGS. 41A-41C. All of these components are arranged on the optical axis Lc.

The objective optical system OL is composed of a first lens group G₁ having positive power and being immovable in magnification change and in focusing, a second lens group G₂ that is a magnification-changing group having negative power and being moved along the optical axis at least in magnification change, a third lens group G₃ having positive power and being immovable in magnification change and in focusing, a fourth lens group G₄ that is a focusing group having negative power and being moved along the optical axis at least in focusing, and a fifth lens group G₅ having positive power and being immovable in magnification change and in focusing, these lens groups being arranged in that order from the object side. The aperture stop S is arranged between the first lens group G₁ and the second lens group G₂ in such a way that the aperture stop S moves integrally with the second lens group G₂.

The first lens group G₁ is composed of: a lens L₁₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; a lens L₁₂ that is a plano lens; a lens L₁₃ that is a meniscus lens having negative power with the convex surface thereof facing the image side; a lens L₁₄ that is a biconvex lens having positive power; and a lens L₁₅ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₁₄ and the lens L₁₅ are joined to each other.

The second lens group G₂ is composed of: a lens L₂₁ that is a plano-concave lens having negative power with the concave surface thereof facing the image side; and a lens L₂₂ that is a meniscus lens having negative power with the concave surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₂₁ and the lens L₂₂ are joined to each other.

The third lens group G₃ is composed of a lens L₃₁ that is a biconvex lens having positive power.

The fourth lens group G₄ is composed of a lens L₄₁ that is a plano-concave lens having negative power with the planar surface thereof facing the image side.

The fifth lens group G₅ is composed of: a lens L₅₁ that is a biconvex lens having positive power; and a lens L₅₂ that is a meniscus lens having negative power with the convex surface thereof facing the image side, these lenses being arranged in that order from the object side. The lens L₅₁ and the lens L₅₂ are joined to each other.

An amount of variation in magnification per movement of the second lens group G₂ is larger than an amount of variation in magnification per movement of the fourth lens group G₄ in this objective optical system OL.

This observation apparatus is formed in such a way that movement of the second lens group G₂ along the optical axis can change the observation state of the objective optical system reversibly and continuously: from the normal observation state in which a plurality of objects to be imaged exist in an observation area; to the close-up observation state in which the objective optical system is closed to a particular object optionally selected from these objects to be imaged by an observer so as to observe the particular object in detail.

In addition, this observation apparatus is formed in such a way that accurate focusing can be performed in every observation state of the objective optical system by moving not only the second lens group G₂ but also the fourth lens group G₄ along the optical axis.

Next, numerical data on the optical system provided for this observation apparatus is shown.

Numerical Data 20

Unit: mm Surface data Radius of Surface Refractive Abbe's Surface No. curvature distance index number s r d nd νd  1 ∞ 0.36 1.88300 40.76  2 1.150 0.99  3 ∞ 0.31 1.51400 73.43  4 ∞ 1.75  5 −2.409 1.02 2.00330 28.27  6 −2.530 0.30  7 2.609 0.54 1.77250 49.60  8 −3.116 0.31 1.92286 18.90  9 −9.579 D9 10 (Stop surface) ∞ 0.03 11 ∞ 0.28 1.48749 70.23 12 1.837 0.30 1.59270 35.31 13 1.202 D13 14 3.296 0.86 1.72916 54.68 15 −5.680 D15 16 −6.950 0.30 1.92286 20.88 17 ∞ D17 18 1.950 1.44 1.48749 70.23 19 −1.800 0.30 1.92286 18.90 20 −13.069 0.30 21 ∞ 0.40 1.52300 58.50 22 ∞ 0.30 23 (Image plane) ∞ Observation state Normal Middle Close-up Close-up observation observation observation observation (the farthest (the farthest (the farthest (the nearest point) point) point) point) Various data on objective optical system Zoom ratio: 1.26 Focal length 0.95 1.00 1.05 0.99 F number 5.43 5.47 5.47 5.17 Angle of view 144.58 126.63 113.19 126.97 (2ω) Image height 0.85 0.85 0.85 0.85 Total length 14.29 14.13 13.95 13.72 (in air) BF (in air) 0.79 0.63 0.45 0.22 Surface distance D9 0.30 0.44 0.58 0.58 D13 2.50 2.36 2.22 2.22 D15 0.80 0.80 0.80 1.30 D17 0.80 0.80 0.80 0.30 Data on lens groups Group The first surface of lens group Focal length 1 1 0.89 2 11 −2.31 3 14 2.97 4 16 −7.45 5 18 8.55 Data on conditions Condition (10): 3 < (m_(c-d)/m_(u-d))/(m_(c-n)/m_(c-d)) < 11: 3.011 Condition (11): |ΔDT_(f)| < 2: 1.783 Condition (12): 0.2 < |(1 − β_(f) · β_(f)) × β_(f)′ · β_(f)′| < 0.9: 0.6204 Condition (13): 1 < |m_(c-n)/m_(c-d)| < 2: 1.649 Condition (14): 0.7 < |F_(f)/F_(v)| < 8: 3.219 Condition (15): |γ| < 11.5: 5.698 Condition (16): |DT_(c-n) − DT_(c-d)| < 5: 2.846 Condition (17): DT_(u-d) < −50: −62.30 Condition (18): 2 < |F_(f)/F_(c-d)| < 15: 7.114 Condition (19): 0.83 < Fno_(u)/Fno_(c): 0.992

Besides, lenses constituting objective optical systems according to the present invention are limited to the shapes of or the number of the lenses shown in each of the above-described Embodied Examples. For example, lenses which substantially have no refractive power are arranged in or outside lens groups respectively in each of the above-described Embodied Examples (the lens L₁₂ which is arranged in the first lens group G₁ in the Embodied Example 3 and the plano lens PL which is arranged on the image side of the objective optical system OL). However, these lenses are not always arranged in objective apparatuses according to the present invention. Also, conversely, a lens which is not shown in the drawings of the respective above-described Embodied Examples and substantially has no refractive power may be arranged in or outside a lens group.

Also, with respect to lenses constituting objective optical systems according to the present invention, there is no necessity that the first movable lens group, the second movable lens group, the magnification-changing group, and the focusing group have to be composed of a single lens component, and the first movable lens group, the second movable lens group, the magnification-changing group, and the focusing group may be composed of a plurality of lens components.

Next, one example of endoscopes which are provided with an objective optical systems according to the present invention respectively is explained. FIG. 43 is a view is showing the whole of an endoscope which is provided with an objective optical system according to the present invention. Besides, the endoscopes shown in FIG. 43 includes: an insertion unit 1 which is inserted into the body of a patient; an endoscope-operation unit 2; a control unit 3 which is provided with a light source unit and an image-processing unit inside; and a monitor 4 which displays images outputted from the control unit 3. And, an objective optical system according to the present invention is provided in the front end 1 a of the insertion unit 1. 

What is claimed is:
 1. An objective optical system comprising: an immovable lens group arranged nearest to an object side, the immovable lens group being fixedly positioned in a focusing operation; and a first movable lens group and a second movable lens group, at least one of which moves along an optical axis in a focusing operation, wherein the immovable lens group has, at a position nearest to the object side, a lens component having a negative power, wherein an amount of variation in magnification per unit movement of the first movable lens group is different from an amount of variation in magnification per unit movement of the second movable lens group, and wherein the objective optical system is configured: to allow the first movable lens group to move alone along the optical axis while the second movable lens group is fixedly positioned; and to allow the second movable lens group to move alone along the optical axis while the first movable lens group is fixedly positioned.
 2. The objective optical system according to claim 1, wherein the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged, and the amount of variation in magnification per unit movement of the first movable lens group is larger than the amount of variation in magnification per unit movement of the second movable lens group.
 3. The objective optical system according to claim 1, wherein the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged, and the amount of variation in magnification per unit movement of the first movable lens group is smaller than the amount of variation in magnification per unit movement of the second movable lens group.
 4. An objective optical system with reversibly and continuously changeable observation state from a normal observation state to a close-up observation state achieved by movement of a predetermined lens group, comprising: an immovable lens group which is arranged nearest to an object side and having a negative power, the immovable lens group being fixedly positioned in a focusing operation and being fixedly positioned in an observation-state changing operation; and a first movable lens group and a second movable lens group, at least one of which moves along an optical axis in a focusing operation, wherein the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged, wherein an amount of variation in magnification per unit movement of the first movable lens group is smaller than an amount of variation in magnification per unit movement of the second movable lens group, wherein an observation-state changing operation is made by movement of the second movable lens group, and wherein the objective optical system is configured: to allow, in an observation-state changing operation in a range from the normal observation state to the close-up observation state, the second movable lens group to move alone along the optical axis while the first movable lens group is fixedly positioned; and to allow, in a focusing operation, the first movable lens group to move alone along the optical axis while the second movable lens group is fixedly positioned.
 5. The objective optical system according to claim 4, wherein the following condition is satisfied: 3<(m _(c-d) /m _(u-d))/(m _(c-n) /m _(c-d))<10 where, m_(c-d) denotes a transverse magnification of the objective optical system as a whole in a farthest point state in the close-up observation state, m_(u-d) denotes a transverse magnification of the whole of the objective optical system as a whole in a farthest point state in the normal observation state, and m_(c-n) denotes a transverse magnification of the objective optical system as a whole in a nearest point state in the close-up observation state.
 6. The objective optical system according to claim 4, wherein the following condition is satisfied: 1<m _(c-n) /m _(c-d)<1.55 where, m_(c-n) denotes a transverse magnification of the objective optical system as a whole in a nearest point state in the close-up observation state, and m_(c-d) denotes a transverse magnification of the objective optical system as a whole in a farthest point state in the close-up observation state.
 7. The objective optical system according to claim 4, wherein the objective optical system comprises a lens group that is located nearer to an image side than the first movable lens group is located, and the following condition is satisfied: 0.2<|(1−β₁·β₁)×β₁′·β₁∝|<3 where, β₁ denotes a transverse magnification of the first movable lens group and β₁′ denotes a transverse magnification of the lens group which that is located nearer to the image side than the first movable lens group is.
 8. The objective optical system according to claim 4, wherein the following condition is satisfied: 2<|F ₁ /F _(c-d)|<8 where, F₁ denotes a focal length of the first movable lens group and F_(c-d) denotes a focal length of the whole of the objective optical system as a whole in a farthest point state in the close-up observation state.
 9. The objective optical system according to claim 4, wherein the following condition is satisfied: 1.8<|F ₂ /F _(c-d)|<5 where, F₂ denotes a focal length of the second movable lens group and F_(c-d) denotes a focal length of the objective optical system as a whole in a farthest point state in the close-up observation state.
 10. The objective optical system according to claim 4, wherein the following condition is satisfied: 0.02<D ₁ /L<0.12 where, D₁ denotes a sum of an air spacing from a lens group located on the object side of the first movable lens group to the first movable lens group and an air spacing from the first movable lens group to a lens group located on an image side of the first movable lens group, and L denotes a total length of the objective optical system as a whole.
 11. The objective optical system according to claim 4, wherein the following condition is satisfied: |DT _(c-n) −DT _(c-d)|<5 where, DT_(c-n) denotes a distortion of an image at an image height ratio of 1.0 in a nearest point state in the close-up observation state and D_(c-d) denotes a distortion of an image at an image height ratio of 1.0 in a farthest point state in the close-up observation state.
 12. The objective optical system according to claim 4, wherein the following condition is satisfied: DT _(u-d)<−50 where, DT_(u-d) denotes a distortion of an image at an image height ratio of 1.0 in a farthest point state in the normal observation state.
 13. The objective optical system according to claim 4, wherein the following condition is satisfied: Fno _(u) /Fno _(c)>0.94 where, Fno_(u) denotes an F number of the objective optical system as a whole in the normal observation state and Fno_(c) denotes an F number of the objective optical system as a whole in the close-up observation state.
 14. The objective optical system according to claim 4, wherein lenses included in the objective optical system are divided into five lens groups, of which a lens group arranged second nearest to the object side is the first movable lens group and a lens group arranged fourth nearest to the object side is the second movable lens group.
 15. An observation apparatus comprising the objective optical system according to claim 4 and an autofocus mechanism for moving the first movable lens group.
 16. An objective optical system which reversibly and continuously variable magnification from a normal observation state to a close-up observation state achieved by movement of a predetermined lens group, comprising: an immovable lens group arranged nearest to an object side, the immovable lens group being fixedly positioned in a magnification changing operation and being fixedly positioned in a focusing operation; a magnification-changing group which moves along an optical axis at least in a magnification-changing operation; and a focusing group which moves along the optical axis at least in a focusing operation, wherein a lens arranged nearest to the object side in the immovable lens group has a negative power, wherein the magnification-changing group is arranged nearer to the object side than the focusing group is arranged, wherein an amount of variation in magnification per unit movement of the magnification-changing group is larger than an amount of variation in magnification per unit movement of the focusing group, wherein a change in magnification is made by movement of the magnification-changing group, and wherein the objective optical system is configured: to allow, in a magnification changing operation in a range from the normal observation state to the close-up observation state, the magnification-changing group to move alone along the optical axis while the focusing group is fixedly positioned; and to allow, in a focusing operation, the focusing group to move alone along the optical axis while the magnification-changing group is fixedly positioned.
 17. The objective optical system according to claim 16, wherein the following condition is satisfied: 3<(m _(c-d) /m _(u-d))/(m _(c-n) /m _(c-d))<11 where, m_(c-d) denotes a transverse magnification of the objective optical system as a whole in a farthest point state in the close-up observation state, m_(u-d) denotes a transverse magnification of the objective optical system as a whole in a farthest point state in the normal observation state, and m_(c-n) denotes a transverse magnification of the objective optical system as a whole in a nearest point state in the close-up observation state.
 18. The objective optical system according to claim 16, wherein the following condition is satisfied when the focusing group moves in such a way as to shift an image plane by ±(F number×0.005) mm within a region from a farthest point to a nearest point in the close-up observation state: |ΔDT _(f)|<2 where, ΔDT_(f) denotes a variation in distortion when the focusing group moves.
 19. The objective optical system according to claim 16, wherein the objective optical system comprises a lens group that is located nearer to an image side than the focusing group is located, and the following condition is satisfied: 0.2<|(1−β_(f)·β_(f))×β_(f)′·β_(f)′|<0.9 where, β_(f) denotes a transverse magnification of the focusing group in a farthest point state in the close-up observation state and β_(f)′ denotes a transverse magnification of a lens group that is located nearer to the image side than the focusing group is in the farthest point state in the close-up observation state.
 20. The objective optical system according to claim 16, wherein the focusing group is arranged nearest to an image side, and the following condition is satisfied: 0.2<(1−β_(f)·β_(f))<0.9 where, β_(f) denotes a transverse magnification of the focusing group in a farthest point state in the close-up observation state.
 21. The objective optical system according to claim 16, wherein the following condition is satisfied: 1<|m _(c-n) /m _(c-d)|<2 where, m_(c-n) denotes a transverse magnification of the objective optical system as a whole in a nearest point state in the close-up observation state and m_(c-d) denotes a transverse magnification of the objective optical system as a whole in a farthest point state in the close-up observation state.
 22. The objective optical system according to claim 16, wherein the following condition is satisfied: 0.7<F _(f) /F _(v)|<8 where, F_(f) denotes a focal length of the focusing group and F_(v) denotes a focal length of the magnification-changing group.
 23. The objective optical system according to claim 16, wherein the following condition is satisfied: |γ|<11.5 where, γ denotes an angle formed between an optical axis and a principal ray of light that is emergent from a lens nearest to an image side in the focusing group to form an image with an image height ratio of 1.0 in a nearest point state in the close-up observation state.
 24. The objective optical system according to claim 16, wherein the following condition is satisfied: |DT _(c-n) −DT _(c-d)<5 where, DT_(c-n) denotes a distortion of an image at an image height ratio of 1.0 in a nearest point state in the close-up observation state and DT_(c-d) denotes a distortion of an image at an image height ratio of 1.0 in a farthest point state in the close-up observation state.
 25. The objective optical system according to claim 16, wherein the following condition is satisfied: DT ₁₃₅<−50 where, DT₁₃₅ denotes a distortion at an angle of view of 135 degrees.
 26. The objective optical system according to claim 16, wherein at least one of the magnification-changing group and the focusing group consists of a single lens component.
 27. The objective optical system according to claim 16, wherein the objective optical system further comprises a stop and the focusing group is arranged nearer to an image side than the stop is arranged.
 28. An observation apparatus comprising the objective optical system according to claim 16 and an autofocus mechanism for moving the focusing group.
 29. An objective optical system comprising: an immovable lens group arranged nearest to an object side, the immovable lens group being fixedly positioned in a focusing operation; and a first movable lens group and a second movable lens group, at least one of which moves along an optical axis in a focusing operation, wherein the immovable lens group has, at a position nearest to the object side, a lens component having a negative power, wherein an amount of variation in magnification per unit movement of the first movable lens group is different from an amount of variation in magnification per unit movement of the second movable lens group, and wherein the optical system further comprises a second immovable lens group arranged between the first movable lens group and the second movable lens group, the second immovable lens group being fixedly positioned in a focusing operation.
 30. The objective optical system according to claim 29, wherein the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged, and the amount of variation in magnification per unit movement of the first movable lens group is larger than the amount of variation in magnification per unit movement of the second movable lens group.
 31. The objective optical system according to claim 29, wherein the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged, and the amount of variation in magnification per unit movement of the first movable lens group is smaller than the amount of variation in magnification per unit movement of the second movable lens group.
 32. The objective optical system according to claim 1, wherein, of all lens groups included in the objective optical system as a whole, a number of lens groups movable along an optical axis is two.
 33. The objective optical system according to claim 4, wherein, of all lens groups included in the objective optical system as a whole, a number of lens groups movable along an optical axis is two.
 34. The objective optical system according to claim 16, wherein, of all lens groups included in the objective optical system as a whole, a number of lens groups movable along an optical axis is two.
 35. The objective optical system according to claim 29, wherein, of all lens groups included in the objective optical system as a whole, a number of lens groups movable along an optical axis is two.
 36. An objective optical system with reversibly and continuously changeable observation state from a normal observation state to a close-up observation state achieved by movement of a predetermined lens group, comprising: an immovable lens group arranged nearest to an object side and having a negative power, the immovable lens group being fixedly positioned in a focusing operation and being fixedly positioned in an observation-state changing operation; and a first movable lens group and a second movable lens group, at least one of which moves along an optical axis in a focusing operation, wherein the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged, wherein an amount of variation in magnification per unit movement of the first movable lens group is smaller than an amount of variation in magnification per unit movement of the second movable lens group, wherein an observation-state changing operation is made by movement of the second movable lens group, and wherein the following condition is satisfied: 3<(m _(c-d) /m _(u-d))/(m _(c-n) /m _(c-d))<10 where, m_(c-d) denotes a transverse magnification of the objective optical system as a whole in a farthest point state in the close-up observation state, m_(u-d) denotes a transverse magnification of the objective optical system as a whole in a farthest point state in the normal observation state, and m_(c-n) denotes a transverse magnification of the objective optical system as a whole in a nearest point state in the close-up observation state.
 37. An objective optical system with reversibly and continuously changeable observation state from a normal observation state to a close-up observation state achieved by movement of a predetermined lens group, comprising: an immovable lens group arranged nearest to an object side and having a negative power, the immovable lens group being fixedly positioned in a focusing operation and being fixedly positioned in an observation-state changing operation; and a first movable lens group and a second movable lens group, at least one of which moves along an optical axis in a focusing operation, wherein the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged, wherein an amount of variation in magnification per unit movement of the first movable lens group is smaller than an amount of variation in magnification per unit movement of the second movable lens group, wherein an observation-state changing operation is made by movement of the second movable lens group, and wherein the objective optical system comprises a lens group that is located nearer to an image side than the first movable lens group is located, and the following condition is satisfied: 0.2<|(1−β₁·β₁)×β₁′·β₁∝|<3 where, β₁ denotes a transverse magnification of the first movable lens group and β₁′ denotes a transverse magnification of the lens group that is located nearer to the image side than the first movable lens group is.
 38. An objective optical system with reversibly and continuously changeable observation state from a normal observation state to a close-up observation state achieved by movement of a predetermined lens group, comprising: an immovable lens group arranged nearest to an object side and having a negative power, the immovable lens group being fixedly positioned in a focusing operation and being fixedly positioned in an observation-state changing operation; and a first movable lens group and a second movable lens group, at least one of which moves along an optical axis in a focusing operation, wherein the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged, wherein an amount of variation in magnification per unit movement of the first movable lens group is smaller than an amount of variation in magnification per unit movement of the second movable lens group, wherein an observation-state changing operation is made by movement of the second movable lens group, and wherein the following condition is satisfied: DT _(u-d)<−50 where, DT_(u-d) denotes a distortion of an image at an image height ratio of 1.0 in a farthest point state in the normal observation state.
 39. An objective optical system with reversibly and continuously changeable observation state from a normal observation state to a close-up observation state achieved by movement of a predetermined lens group, comprising: an immovable lens group arranged nearest to an object side and having a negative power, the immovable lens group being fixedly positioned in a focusing operation and being fixedly positioned in an observation-state changing operation; and a first movable lens group and a second movable lens group, at least one of which moves along an optical axis in a focusing operation, wherein the first movable lens group is arranged nearer to the object side than the second movable lens group is arranged, wherein an amount of variation in magnification per unit movement of the first movable lens group is smaller than an amount of variation in magnification per unit movement of the second movable lens group, wherein an observation-state changing operation is made by movement of the second movable lens group, and wherein lenses included in the objective optical system are divided into five lens groups, of which a lens group arranged second nearest to the object side is the first movable lens group and a lens group arranged fourth nearest to the object side is the second movable lens group.
 40. An objective optical system with reversibly and continuously variable magnification from a normal observation state to a close-up observation state achieved by movement of a predetermined lens group, comprising: an immovable lens group arranged nearest to an object side, the immovable lens group being fixedly positioned in a magnification changing operation and being fixedly positioned in a focusing operation; a magnification-changing group which moves along an optical axis at least in a magnification changing operation; and a focusing group which moves along the optical axis at least in a focusing operation, wherein a lens arranged nearest to the object side in the immovable lens group has a negative power, wherein the magnification-changing group is arranged nearer to the object side than the focusing group is arranged, wherein an amount of variation in magnification per unit movement of the magnification-changing group is larger than an amount of variation in magnification per unit movement of the focusing group, wherein a change in magnification is made by movement of the magnification-changing group, and wherein the following condition is satisfied: 3<(m _(c-d) /m _(u-d))/(m _(c-n) /m _(c-d))<11 where, m_(c-d) denotes a transverse magnification of the objective optical system as a whole in a farthest point state in the close-up observation state, m_(u-d) denotes a transverse magnification of the objective optical system as a whole in a farthest point state in the normal observation state, and m_(c-n) denotes a transverse magnification of the objective optical system as a whole in a nearest point state in the close-up observation state.
 41. An objective optical system with reversibly and continuously variable magnification from a normal observation state to a close-up observation state achieved by movement of a predetermined lens group, comprising: an immovable lens group arranged nearest to an object side, the immovable lens group being fixedly positioned in a magnification changing operation and being fixedly positioned in a focusing operation; a magnification-changing group which moves along an optical axis at least in a magnification changing operation; and a focusing group which moves along the optical axis at least in a focusing operation, wherein a lens arranged nearest to the object side in the immovable lens group has a negative power, wherein the magnification-changing group is arranged nearer to the object side than the focusing group is arranged, wherein an amount of variation in magnification per unit movement of the magnification-changing group is larger than an amount of variation in magnification per unit movement of the focusing group, wherein a change in magnification is made by movement of the magnification-changing group, and wherein the following condition is satisfied: |γ|<11.5 where, γ denotes an angle formed between an optical axis and a principal ray of light that is emergent from a lens nearest to an image side in the focusing group to form an image with an image height ratio of 1.0 in a nearest point state in the close-up observation state.
 42. An objective optical system with reversibly and continuously variable magnification from a normal observation state to a close-up observation state achieved by movement of a predetermined lens group, comprising: an immovable lens group arranged nearest to an object side, the immovable lens group being fixedly positioned in a magnification changing operation and being fixedly positioned in a focusing operation; a magnification-changing group which moves along an optical axis at least in a magnification changing operation; and a focusing group which moves along the optical axis at least in a focusing operation, wherein a lens arranged nearest to the object side in the immovable lens group has a negative power, wherein the magnification-changing group is arranged nearer to the object side than the focusing group is arranged, wherein an amount of variation in magnification per unit movement of the magnification-changing group is larger than an amount of variation in magnification per unit movement of the focusing group, wherein a change in magnification is made by movement of the magnification-changing group, and wherein the following condition is satisfied: DT ₁₃₅<50 where, DT₁₃₅ denotes a distortion at an angle of view of 135 degrees. 